Worms and Worm Mitigation

Worms and Worm Mitigation Saman Amarasinghe Associate Professor, MIT EECS/CSAIL CTO, Determina Inc.

Outline • Worm Basics • Program Shepherding • Intrusion Prevention Systems • Anatomy of an Attack • The Determina Story

What is a worm? • Virus - a code segment which replicates by attaching copies to existing executables. • Self-replication • Requires a host program as a carrier • Activated by external action • Worm - a program which replicates itself and causes execution of the new copy. • Self-replication • Self-contained; does not require a host • Activated by hijacking or creating a process • Virus - a code segment which replicates by attaching copies to existing executables. • Worm - a program which replicates itself and causes execution of the new copy.

Types of Worms • E-mail based worm • The payload arrives as an e-mail attachment • Payload gets executed • Social Engineering or • Program vulnerability • Self propagate • Memory based worm • The payload arrive as packets on an open port • Takes advantage of a program vulnerability • Hijacks the program • Self propagate

History of Worms 1982 PARC “Worms as an administrative tool” • Perform legitimate tasks on a distributed system 1987 “Christmas Tree Exec” • attacked IBM mainframes • E-mail with a program that displayed a x-mas tree, but also send it to everyone in the user’s address book 1988 “The Morris Worm” • First true internet worm • Attacked both Sun and DEC unix systems • Used TCP/IP, attacked known OS bugs and admin flows • Automatic penetration, activation and propagation • Brought down the Internet for the first time ………. 2001 Code Red Worm 2003 Slammer Worm 2003 Blaster Worm 2004 Sasser Worm 2004 Witty Worm

Today’s Worm Threat • “One of the biggest threats to the modern information infrastructure” • Characteristics of Modern Worm Threat • Relatively rare (two a year) • Extreme rapid propagation • human vs. machine speed • Infects millions of systems • May or may not cause real damage • Catastrophic situations for many enterprises • Example: Blaster and CSX

Worldwide Code Red Infections 700,000 machines infected $2-2.9 billion in damage (Computer Economics) $200 million in damage per day during attacks

Program Shepherding Outline • Memory based attacks • Motivating Example: A buffer overflow attack • Dissecting the lifecycle in the penetration phase • Overview of Program Shepherding • DynamoRIO basics • Technique 1: Restricted Code Origins • Technique 2: Restricted Control Transfer • Technique 3: Uncircumventable Sandboxing • Self Protection

Memory Based Attacks • Attack that that directly enters an application, corrupts the application’s memory and hijack the application • Types of memory based attacks • Buffer Overflow • Heap Manipulation • Format String Vulnerabilities • Shatter Attacks • Return to Libc Attacks • Danger of Memory-based attacks • Once the application is hijacked, the attack can do anything that the application can do • Modern server applications run with a lot of privileges

Network Arguments: … Return Address Local Variables: … Application Data Argument: h Return Address Local Variables: tmp Local Variables: URL Instructions Operating System An Example: Buffer Overflow Attack Code Stack handle_URL(handle * h) { char url[64]; … char * tmp =geturl(h) strcpy(url, tmp); … }

An Example: Buffer Overflow Attack Network Program Counter: Executes the Program Instruction by Instruction Application Data Instructions Operating System

An Example: Buffer Overflow Attack Code Stack handle_URL(handle * h) { char url[64]; … char * tmp =geturl(h) strcpy(url, tmp); … } Arguments: … Return Address Local Variables: … Argument: h Return Address Local Variables: tmp Local Variables: URL URL: http://cag.lcs.mit.edu/~saman/tmp/doitnow.pl?helper=“foobar”myid=123453;junk=23#42@$@FFNLQ!_@##*RFNL!~@#+

Enter An Example: Buffer Overflow Attack Network Application Data Instructions Operating System

An Example: Buffer Overflow Attack Code Stack handle_URL(handle * h) { char url[64]; … char * tmp =geturl(h) strcpy(url, tmp); … } Arguments: … 0x12FA2 lea %ecx%eax sub 0x1c(%edi) %eax movzx 0x8(%edi) %ecx shl $0x07 %ecx cmp %eax %ecx ………… Return Address Local Variables: … Malicious code segment Argument: h Return Address 0x12FA2 0x12FA2 Local Variables: tmp Local Variables: URL URL: http://0011101101101110110100010101101011010101101101 10110110110110101011010101010110101011010101010110...

Enter Hijack Attack An Example: Buffer Overflow Attack Network Application Data Instructions Operating System

Restricted Execution Environment Stop Applications From Being Hijacked When to stop an attack? • Enter • Monitoring is simple • Port monitoring or system call monitoring • Don’t know good guy from bad guy • only known criminals can be identified • Even known bad guys are hard to detect • encrypted channels • Attack • Monitoring can be done • System call monitoring • Hard to distinguish between actions of a normal program vs. a compromised program • Leads to false positives ABI • Hijack • “Catch in the act of criminal behavior” • All programs follow strict conventions • ABI (Application Binary Interface) • The Calling Convention • Currently no enforcement • All attacks violate some of these conventions • Enforcing conventions • Systematically catch an entire class of attacks • No false positives • Catch them before they do ANY bad activity  no attack code is ever run • Conventional Wisdom: Impossible to do without a large performance penalty • Need to be inside the application • Need to monitor activity at a very fine-grain – each instruction at a time • Overhead will be overwhelming • Program Shepherding lets you do just that! • Able to amortize the cost of enforcement, eliminating the overhead Processor Execution Environment

call call jmp jmp br br ret How Program Shepherding Work? Program Counter: Executes the Program Instruction by Instruction Run-time System Never Let go of the Program Counter Code Cache Program Restricted Code Origins: Is this code came from a code page? Restricted Code Origins: Is this code came from a code page? Restricted Code Origins: Is this code came from a code page? Restricted Control Transfer: Is it legal to go from here to there? Restricted Control Transfer: Is it legal to go from here to there?

A Basic Interpreter next VPC • Never give up the Program Counter (PC) • PC is in the interpreter fetch next instruction update VPC decode execute Validate exception handling Instruction Interpreter

Performance of the Basic Interpreter Slowdown factor

Trick I: Adding a Code Cache next VPC lookup VPC exception handling fetch block at VPC execute block emit block context switch BASIC BLOCK CACHE non-control-flow instructions

Adding a Basic Block CachePerformance Effect Slowdown factor Slowdown factor • Performance Problem: High cost of frequent context switches

Trick II: Linking next VPC lookup VPC exception handling fetch block at VPC link block emit block execute until cache miss context switch BASIC BLOCK CACHE non-control-flow instructions

Performance Effect of Basic Block Cache with direct branch linking Slowdown factor • Performance Problem: High cost of mispredicted indirect branches

Trick III: Efficient Indirect Branch Handling next VPC basic block builder context switch miss BASIC BLOCK CACHE miss indirect branch lookup non-control-flow instructions

Performance Effect of indirect branch linking • Performance Problem: inefficient code layout in code cache Slowdown factor

Trick IV: Picking Traces trace selector basic block builder START dispatch context switch BASIC BLOCK CACHE TRACE CACHE indirect branch lookup non-control-flow instructions non-control-flow instructions

Performance Effect of Picking Traces 300 Slowdown factor

Application ntdll.dll / *32.dll Monitor all Control Transfers • Must intercept all windows initiated control transfer events • Exceptions • Call backs in Windows • Asynchronous procedure calls • Setjmp/longjmp • Set thread context Code Cache Kernel Windows

Transparent to the Application • Application behavior cannot change! • No assumptions beyond the ISA and the OS interface • Actions of DynamoRIO is transparent to the application • Data Transparency • I/O Transparency • Transparent Exception Handling • Program Address Transparency

As code is copied to the code cache, check where it’s coming from Check the security policy only once Technique 1: Restricted Code Origins Code Cache Unmodified code pages D A Modified pages B E

Technique 1: Restricted Code Origins • Catches all the injected code attacks • Most of the popular attacks are of this type • What is left? • Malicious reuse of existing code • Change addresses used by return and indirect jump and indirect branch instructions • Much more difficult

An Example: Chained Call Attack Code Stack handle_URL(handle * h) { char url[64]; … char * tmp =geturl(h) strcpy(url, tmp); … } Arguments: … Fake arguments Return Address Local Variables: … 0x8A234 Fake arguments Argument: h Return Address 0x7F8B0 Local Variables: tmp Local Variables: URL Libraries 0x7F8B0 setuid() … 0x8A234 unlink() … URL: http://001110110110111011010001010110101101010110 10110110110110101011010101010110101011010101...

Technique 2:Restricted Control Transfers context switch BASIC BLOCK CACHE TRACE CACHE trace branch taken? indirect branch lookup non-control-flow instructions non-control-flow instructions Restrict based on source address, destination address, and/or transfer type

Technique 2:Restricted Control Transfers • Inter-Segment Indirect Calls and Jumps • Only to known function entry points • Only if the function is exported by the destination segment • Only if the function is imported by the source segment • Intra-Segment Jumps • Only within a known function or to a known function entry point • Intra-Segment Indirect Calls • Only to known function entry points

Technique 2:Restricted Control Transfers • Returns • Only to after a call instruction • If a direct call, called function should be the same as the function returning from

Technique 3: Un-circumventable Sandboxing • Typical problem with sandboxing: • If attacker gains control, can bypass checks • DynamoRIO-inserted sandboxing isun-circumventable • DynamoRIO enforces unique entry points

Protecting DynamoRIO Itself • DynamoRIO runs in the application’s address space • Must not allow application to manipulate DynamoRIO data or code cache • How? • Protect Dynamo data structures and the code cache • Sandbox system calls that can change protection and thread behavior

Memory protection

Evaluating an Intrusion Prevention Solution • Accuracy • Maintainability • Scalability • Coverage • Proactivity • Uncircumventability • Containment

1. Accuracy • How much false positives • Frequency of False positives • Impact of a false positive • Why you need and IPS? • Availability vs. Privacy/Integrity

2. Maintainability • What is a typical enterprise like? • How many machines, how many IT people? • Cost of operations… • How do you manage a large enterprise? • What impact maintainability? • Shelfware vs. deployed software

3. Scalability • Requirements to run enterprise-wide… • Critical bottlenecks • Deployment / maintenance • Performance

4. Coverage • What attacks are stopped? • What is the attack landscape? • Is there a map anywhere? • “I have N products, what do they stop and where are the holes?” • How to define the attack landscape? • Look at the past and extrapolate • Look at the vulnerabilities

Most Critical Vulnerabilities % of vulnerabilities Source: CVE, Microsoft Security Bulletins, 2003-2004

Good guys Patch like crazy Application Released With a bug Vulnerability announced Patch released Attack Released Bad guys Analyze patch & create attack 5. Proactivity • What information do you need to stop an attack? • Know the application • Know the vulnerability • Know the attack • Day-zero attacks. • Traditional Timeline of an Attack

Worms and Worm Mitigation

Worms and Worm Mitigation

Presentation Transcript

Viruses and Worms

Worms and Mollusks

Worms, Worms, Worms!

Worms and viruses ;)

WORMS

Worms and Mollusks

Worm

Worm

Worms and Mollusks

Worms and Mollusks

Worms and Mollusks

Modeling, Early Detection, and Mitigation of Internet Worm Attacks

Numbers and worms

Enterprise Worm Mitigation-- A Community of Interest based approach

Worms and Mollusks

Worms and Mollusks

Worms and Mollusks

Viruses and Worms

Modeling, Analysis, and Mitigation of Internet Worm Attacks

Birds and Worms

Red Worm Farms - Red Worms For Sale - RedWormFarms.com

Worms and Botnets