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Code%20Red%20Worm%20Propagation%20Modeling%20and%20Analysis

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Title: Code%20Red%20Worm%20Propagation%20Modeling%20and%20Analysis


1
Code Red Worm Propagation Modeling and Analysis
  • Cliff Changchun Zou, Weibo Gong, Don Towsley
  • Univ. Massachusetts, Amherst

2
Motivation
  • Code Red worm incident of July 19th, 2001
  • Showed how fast a worm can spread.
  • more than 350,000 infected in less than one day.
  • A friendly worm?
  • No real damage to compromised computers.
  • Did not send out flooding traffic.
  • A good model can
  • Predict worm propagation and damage.
  • Understand the worm spreading characteristics.
  • Help to find effective mitigation technique.

3
Code Red worm background
  • Sent HTTP Get request to buffer overflow Win IIS
    server.
  • It generated 100 threads to scan simultaneously
  • One reason for its fast spreading.
  • Huge scan traffic might have caused congestion.
  • Characteristics
  • Uniformly picked IP addresses to send scan
    packets.

4
Epidemic modeling introduction
  • infectious hosts continuously infect others.
  • removed hosts in epidemic area
  • Recover and immune to the virus.
  • Dead because of the disease.
  • removed hosts in computer area
  • Patched computers that are clean and immune to
    the worm.
  • Computers that are shut down or cut off from
    worms circulation.

5
Epidemic modeling introduction
  • Homogeneous assumption
  • Any host has the equal probability to contact any
    other hosts in the system.
  • Number of contacts ? I ? S
  • Code Red propagation has homogeneous property
  • Direct connect via IP
  • Uniformly IP scan

6
Deterministic epidemic models Simple epidemic
model
  • State transition
  • N population S(t) susceptible hosts I(t)
    infectious hosts
  • dI(t)/dt ? S(t) I(t)
  • S(t) I(t) N
  • I(t) ? S(t) symmetric
  • Problems
  • Constant infection rate ?
  • No removed state.

7
Deterministic epidemic models Kermack-McKendrick
epidemic model
  • State transition
  • R(t) removed from infectious ? removal rate
  • dI(t)/dt ? S(t) I(t) dR(t)/dt
  • dR(t)/dt ?I(t) S(t) I(t) R(t) N
  • Epidemic threshold
  • No outbreak if S(0) lt ? / ?.
  • Problems
  • Constant infection rate ?
  • No

I(t)
t
8
Code Red modeling Consider human
countermeasures
  • Human countermeasures
  • Clean and patch download cleaning program,
    patches.
  • Filter put filters on firewalls, gateways.
  • Disconnect computers.
  • Reasons for
  • Suppress most new viruses/worms from outbreak.
  • Eliminate virulent viruses/worms eventually.
  • Removal of both susceptible and infectious hosts.

9
Code Red modeling Consider human
countermeasures
  • Model (extended from KM model)
  • Q(t) removal from susceptible hosts.
  • R(t) removal from infectious hosts.
  • I(t) infectious hosts.
  • J(t) ? I(t)R(t) Number of infected hosts
  • hosts that have ever been infected
  • dS(t)/dt -? S(t) I(t) - dQ(t)/dt
  • dR(t)/dt ?I(t)
  • dQ(t)/dt ?S(t)J(t)
  • S(t) I(t) R(t) Q(t) N

10
Code Red modeling Two-factor worm model
  • Code Red worm may have caused congestion
  • Huge number of scan packets with unused IP
    addresses.
  • Routing table cache misses. ( about 30 of IP
    space is used)
  • Generation of ICMP (router error) in case of
    invalid IP.
  • Possible BGP instability.
  • Effect slowing down of worm propagation rate ?
    ? ?(t)
  • Two-factor worm model
  • dS(t)/dt -?(t)S(t)I(t) - dQ(t)/dt
  • dR(t)/dt ?I(t)
  • dQ(t)/dt ?S(t)J(t)
  • ?(t) ?0 1 - I(t)/N ?
  • S(t) I(t) R(t) Q(t) N

11
Validation of observed data on Code Red
  • Network monitor
  • record Code Red scan traffic into the local
    network.
  • Code Red worm uniformly picked IP to scan.
  • of scans a cite received ? Size of the IP space
    of the cite.
  • of scans a cite received at time t ? Overall
    scans in Internet at t.
  • of infectious hosts sent scans to a cite at
    time t ? Overall infectious hosts in Internet at
    t.
  • Local observation preserves global worm
    propagation pattern.

12
Observed data on Code Red worm
  • Two independent Class B networks x.x.0.0/16
    (1/65536 of IP space)
  • Count of Code Red scan packets and source IPs
    for each hour.
  • Corresponding to infectious hosts I(t) at each
    hour, not infected hosts J(t)I(t)R(t).
  • Uniformly scan IP ? Two networks, same results.

13
Code Red worm modeling Simple epidemic
modeling
  • Staniford et al. used simple epidemic model
    approach.
  • Conclusion from this model
  • At around 2000UTC (1600 EDT), Code Red infected
    almost all susceptible hosts.
  • On average, a worm infected 1.8 susceptible hosts
    per hour.

?
EDT hours (July 19)
14
Code Red worm modeling Simple epidemic
modeling
  • Possible overestimation?
  • Issues on using simple epidemic for Code Red
  • Constant infection rate ? No considering of the
    impact of worm traffic
  • No recovery removal from infectious hosts
  • No patching before infection removal from
    susceptible hosts

15
Code Red modeling numerical analysis
Two-factor model
Two-factor model
  • Conclusions
  • At 2000UTC (1600 EDT), 60 70 have ever been
    infected.
  • Simple epidemic model overestimates worm
    spreading.
  • ? 0.14 14 infectious hosts would be removed
    after an hour.

16
Code Red Modeling If no congestion is
considered
If no congestion considered
  • The congestion assumption is reasonable.

17
Summary
  • We must consider the changing environment when we
    model virus/worm propagation.
  • Human countermeasures/changing of behaviors.
  • Virus/worm impact on Internet infrastructure.
  • Worm modeling limitation
  • Modeling worm continuously spreading part.
  • Homogeneous systems.
  • Future work how to predict before worms
    outbreak?
  • Determine parameters of a virus/worm model.
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