Model-Based Covert Timing Channels: Automated Modeling and Evasion Steven Gianvecchio 1, Haining...

Model-Based Covert Timing Channels:Automated Modeling and Evasion

Steven Gianvecchio1, Haining Wang1, Duminda Wijesekera2, and Sushil Jajodia2

1College of William and Mary2George Mason University

2RAID 2008 Model-Based Covert Timing Channels: Automated Modeling and Evasion

Outline

Background Covert Timing Channels Model-Based Framework Experimental Evaluation

Capacity Detection Resistance

Conclusion


Outline



Conclusion


Background

Covert Channels manipulate shared resources to transfer

information hide communication (or extra communication) exfiltrate sensitive data (e.g., keys,

passwords)


Background

Types of Covert Channels shared resource is the type covert storage channels

(e.g., packet header fields) covert timing channels

(e.g., packet arrival times)


Outline



Conclusion


Main Goals high capacity strong detection resistance

Capacity –

bits/time unit, not bits/symbol

Covert Timing Channels

)(

);(max

XE

YXIC Xt


Covert Timing Channels

OPtimal Capacity (OPC) send information as fast as possible E(X) is small (1,000s of packets/second)

Fixed-average Packet Rate (FPR) send information as fast as possible with a

fixed-average packet rate E(X) is fixed (a few packets/second)


Outline



Conclusion


Model-Based Framework

LEGITTRAFFIC

ANALYZERCOVERT

IPDs

FILTERLEGITIPDs

MODELENCODER TRANSMITTER

COVERTTRAFFIC

TERMS:IPD – INTER-PACKET DELAY

POISSON, WEIBULL, ...

EXPONENTIAL, GAMMA,

PARETO, LOGNORMAL,

MODELS:

MESSAGE

RANDOM NUMBER

INPUT:

The Framework filters and analyzes legitimate traffic encodes and transmits covert traffic


Components

LEGITTRAFFIC

ANALYZERCOVERT

IPDs

FILTERLEGITIPDs


COVERTTRAFFIC



EXPONENTIAL, GAMMA,

PARETO, LOGNORMAL,

MODELS:

MESSAGE

RANDOM NUMBER

INPUT:

Filter filters input for the specified type of traffic

(e.g., outgoing HTTP) outputs legitimate IPDs


Components

LEGITTRAFFIC

ANALYZERCOVERT

IPDs

FILTERLEGITIPDs


COVERTTRAFFIC



EXPONENTIAL, GAMMA,

PARETO, LOGNORMAL,

MODELS:

MESSAGE

RANDOM NUMBER

INPUT:

Analyzer fits the legitimate IPDs to several models

using MLE (blocks of 100 IPDs) selects the model with the lowest RMSE


Components

LEGITTRAFFIC

ANALYZERCOVERT

IPDs

FILTERLEGITIPDs


COVERTTRAFFIC



EXPONENTIAL, GAMMA,

PARETO, LOGNORMAL,

MODELS:

MESSAGE

RANDOM NUMBER

INPUT:

Encoder uses the IDF of the model generates covert IPDs that mimic the

legitimate traffic


Encoding / Decoding

1. Continuize

2. Encode

3. Decode

4. Discretize

scontinuize rrS

ssF

1mod||

)(

ss1

modelencode drFF )(

srrSrF ssdiscretize )1mod)((||)(

ssmodeldecode rdFF )(


Components

LEGITTRAFFIC

ANALYZERCOVERT

IPDs

FILTERLEGITIPDs


COVERTTRAFFIC



EXPONENTIAL, GAMMA,

PARETO, LOGNORMAL,

MODELS:

MESSAGE

RANDOM NUMBER

INPUT:

Transmitter sends out packets with covert IPDs

Receiver and Decoder receive packets and decode message


Model-Based Framework

Implementation Details components run in user space filter, encoder, transmitter written in C; plus

inline assembly for RDTSC analyzer written in MATLAB


Outline



Conclusion


Experimental Evaluation

Test Scenarios LAN, WAN East-to-East, WAN East-to-West

LAN WAN-EE WAN-EW

distance 0.3 mi 525 mi 2660 mi

RTT 1.7ms 59.6ms 87.2ms

IPDV 2.5e-05 2.41e-03 2.1e-04

hops 3 18 13

IPDV – inter-packet delay variation


Test Setup

MB-HTTP Weibull – avg. λ = 0.0371, avg. k = 0.3010 E(X) is 0.3385 (~3 packets/second)

OPC E(X) is 7.31e-3 to 7.87e-5

(1,515 to 12,777 packets/second) FPR

Exponential – λ = 2.954 E(X) is 0.3385 (~3 packets/second)


Theoretical Capacity

channel

LAN WAN-EE WAN-EW

CPP CPS CPP CPS CPP CPS

MB-HTTP 9.39 27.76 4.12 12.19 6.84 20.21

OPC 0.50 6,395 0.50 68.80 0.50 758.54

FPR 12.63 37.32 6.15 18.17 9.59 28.35

CPP – capacity/packet, CPS = capacity/second

LAN, WAN East-East, WAN East-West OPC has highest capacity


Theoretical Capacity

channel

LAN WAN-EE WAN-EW


MB-HTTP 9.39 27.76 4.12 12.19 6.84 20.21

OPC 0.50 6,395 0.50 68.80 0.50 758.54

FPR 12.63 37.32 6.15 18.17 9.59 28.35


LAN, WAN East-East, WAN East-West MB-HTTP and FPR are close


Empirical Capacity

WAN E-E empirical capacity

0

0.2

0.4

0.6

0.8

1

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

bit

em

pir

ica

l ca

pa

cit

y

FPR MB-HTTP

WAN E-E bit error rates

0

0.1

0.2

0.3

0.4

0.5

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

bit

err

or

rate

FPR MB-HTTP

WAN East-East MB-HTTP versus FPR capacity and bit error degrade quickly


Empirical Capacity

WAN E-W empirical capacity

0

0.2

0.4

0.6

0.8

1

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

bit

em

pir

ica

l ca

pa

cit

y

FPR MB-HTTP

WAN E-W bit error rates

0

0.1

0.2

0.3

0.4

0.5

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

bit

err

or

rate

FPR MB-HTTP

WAN East-West MB-HTTP versus FPR capacity and bit error degrade slowly


Empirical Capacity

channel

LAN WAN-EE WAN-EW


MB-HTTP 6.74 19.93 2.15 6.35 5.18 15.31

OPC 0.85 10,899 0.66 91.28 0.98 1,512

FPR 10.95 32.35 4.63 13.67 9.37 27.69


LAN, WAN East-East, WAN East-West OPC again has the highest capacity


Empirical Capacity

channel

LAN WAN-EE WAN-EW


MB-HTTP 6.74 19.93 2.15 6.35 5.18 15.31

OPC 0.85 10,899 0.66 91.28 0.98 1,512

FPR 10.95 32.35 4.63 13.67 9.37 27.69


LAN, WAN East-East, WAN East-West MB-HTTP and FPR are still close


Tests of Shape: Kolmogorov-Smirnov test –

where s1 and s2 are distribution functions

Tests of Regularity: The regularity test (Cabuk 2004) –

26

Detection Resistance

|)()(|max 21 xsxsKSTEST

jijiSTDEVregularity

i

ji ,,,||


KSTEST

LEGIT-HTTP MB-HTTP FPR OPC

sample size mean stddev m. s.d. m. s.d m. s.d

100x2,000 .193 .110 .196 .093 .92 .0 .99 .0

100x10,000 .141 .103 .157 .087 .92 .0 .99 .0

100x50,000 .096 .096 .122 .073 .92 .0 .99 .0

100x250,000 .069 .066 .096 .036 .92 .0 .99 .0

KSTEST scores high mean and low s.d. for FPR and OPC


KSTEST


sample size mean stddev m. s.d. m. s.d m. s.d

100x2,000 .193 .110 .196 .093 .92 .0 .99 .0

100x10,000 .141 .103 .157 .087 .92 .0 .99 .0

100x50,000 .096 .096 .122 .073 .92 .0 .99 .0

100x250,000 .069 .066 .096 .036 .92 .0 .99 .0

KSTEST scores similar mean and s.d. for LEGIT and MB-HTTP


KSTEST

scores for 100x 2,000 packets

0

0.05

0.1

0.15

0.2

0.25

0.3

0.35

0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5

test score

pro

po

rtio

n

LEGIT-HTTP MB-HTTP


0

0.05

0.1

0.15

0.2

0.25

0.3

0.35

0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5

test score

pro

po

rtio

n

LEGIT-HTTP MB-HTTP

KSTEST distribution similar distributions for LEGIT-HTTP and MB-

HTTP scores


KSTEST


0

0.05

0.1

0.15

0.2

0.25

0.3

0.35

0.4

0.45

0.5

0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5

test score

pro

po

rtio

n

LEGIT-HTTP MB-HTTP


0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5

test score

pro

po

rtio

n

LEGIT-HTTP MB-HTTP

KSTEST distribution LEGIT-HTTP and MB-HTTP overlap even

with 250,000 packets


KSTEST


sample size FP TP TP TP

100x2,000 .01 .01 1.00 1.00

100x10,000 .01 .01 1.00 1.00

100x50,000 .01 .01 1.00 1.00

100x250,000 .01 .02 1.00 1.00

KSTEST detection rates FPR and OPC are detected easily


KSTEST



100x2,000 .01 .01 1.00 1.00

100x10,000 .01 .01 1.00 1.00

100x50,000 .01 .01 1.00 1.00

100x250,000 .01 .02 1.00 1.00

KSTEST detection rates FP equals TP for LEGIT and MB-HTTP


regularity


sample size mean mean mean mean

100x2,000 w=100

43.80 38.21 0.34 0.00

100x2,000 w=250

23.74 22.87 0.26 0.00

regularity scores similar mean for LEGIT and MB-HTTP


regularity



100x2,000 w=100

.01 .00 1.00 1.00

100x2,000 w=250

.01 .00 1.00 1.00

regularity detection rates MB-HTTP is not detected at all


regularity



100x2,000 w=100

.01 .00 1.00 1.00

100x2,000 w=250

.01 .00 1.00 1.00

regularity detection rates again FPR and OPC are detected easily


Outline



Conclusion


Conclusion

Model-Based Covert Timing Channels can be built automatically effective even in coast-to-coast scenario capacity is very close to FPR much stronger detection resistance than FPR

and OPC


Conclusion (cont.)

Future Work investigate detection methods for model-

based covert timing channels explore other more advanced covert timing

channel designs (e.g., non-parametric models)


Questions?

Thank You!

Model-Based Covert Timing Channels: Automated Modeling and Evasion Steven Gianvecchio 1, Haining...

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