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The Infeasibility of Quantifying the Reliability of Life-Critical Real-Time Software

The Infeasibility of Quantifying the Reliability of Life-Critical Real-Time Software. introduction. The availability of enormous computing power at a low cost has led to expanded use of digital computers in current applications and their introduction into many new applications.

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The Infeasibility of Quantifying the Reliability of Life-Critical Real-Time Software

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  1. The Infeasibility of Quantifying the Reliability of Life-Critical Real-Time Software

  2. introduction • The availability of enormous computing power at a low cost has led to expanded use of digital computers in current applications and their introduction into many new applications. • Increased performance at a minimal hardware cost. • Software systems which contain more errors.

  3. Software Reliability Terminology: Failure rate per hour: Ultra reliability = < 10-7 Moderate reliability = 10-3 to 10 -7 Low reliability = > 10-3 • Software errors behaves like a stochastic point process. • In a real-time system, the software is periodically scheduled- the probability of software failure is given by the binomial distribution :

  4. p(Sn = k) = pk (1- p)n-k P(sn > 0) = 1 – (1-p)n = 1 – (1 – p)kt k – number of inputs per unit time. To simplify: P(Sn > n) = 1- e-ktp

  5. Analyzing Software as a Black Box • 1. Testing with replacement - Dt = y0* (r/n) • 2. Testing without replacement - Dt = y0* • Y0 - mean failure time of a test specimen. • For probability of failure of 10–9 for a 10 hour mission: y0 = 10 / -ln(1- 10–9) 1010

  6. (r = 1) No. of replicates (n) Expected Test Duration Dt

  7. Reliability Growth Models • The software design involves a repetitive cycle of testing and repairing a program. The result is a sequence of programs : p1 ,…. pn and a sequence of failure times , t1 ,…. tn.. • The goal is the predict the reliability of the pn.. Experiment performed by Nagel and Skrivan: Program A1: number of bugs Removed failure probability per input

  8. Calculation the requirements per input : p = -ln(1- paye) / Kt Paye = 10-9 for a 10 hour mission , k = 10/sec then: P = 2.78 * 10-15 Extrapolation to predict when ultra reliability will be reached

  9. -To get a rate of 2.78*10-15 you need about 24 bugs. -Bug 23 will have a failure rate of about 9.38*10-15 , the expected number of test cases until observing a binomial event of probability 9.38*10-15 is 1.07*10-14 . -If each test case would require 0.10 sec then the expected time to discover bug 23 alone would be 1.07*1013 sec or 3.4*105 years.

  10. Results for 5 different programs:

  11. Low Sample Rate Systems and Accelerated Testing R = test time per input 1/p = number of inputs until the next bug appears • Dt = R/p Therefore Dt = RKt / -ln(1 - paye). K = number of inputs per unit time.

  12. Reliability Growth Models and Accelerated Testing If the sample rate is 1 input per minute then the failure rate per input must be less than 10-9/60 = 1.67*10-11 bug failure rate per input -The removal of the last bug alone would take approximately 2.2*1010 test cases. Even if the testing process were 60/1000 sec testing would take 42 years

  13. Summary for all the programs: Test Time To Remove the Last Bug to Obtain Ultra reliability

  14. Models of Software Fault Tolerance • independence assumption enables quantification in the ultra reliable region • Quantification of fault-tolerant software reliability is unlikely without the independence assumption • independence assumption cannot be experimentally justified for ultra reliable region

  15. Independence enables quantification of ultra reliability Ei,k = The event that the I version fails on its k execution. Pi,k= The probability that version I fails during the k execution. -The probability that two or more versions fail on the kth execution : Paye ,k = P( (E1,k ^E2,k) or (E1,k ^E3,k)or (E2,k ^E3,k) or (E1,k ^ E2,k ^E3,k)) = P(E1,k ^E2,k) + P (E1,k ^E3,k)+ P(E2,k ^E3,k) - 2P(E1,k ^ E2,k ^E3,k). = P(E1,k )P(E2,k ) + P(E1,k )P(E3,k ) + P(E2,k )P(E3,k ) – 2P(E1,k )P(E2,k )P(E3,k )  Paye ,k = 3p2 - 2p3 3p2

  16. Paye (T) = 1- e(-3p^2*KT) 3p2KT If T = 1 ,k = 3600 (1 execution per second) and P(E1,k ) = 10-6 then we get Paye (T) = 1.08*10-8

  17. Ultra reliable Quantification Is Infeasible Without Independence Paye = P(E1 ^E2) + P (E1 ^E3)+ P(E2 ^E3) - 2P(E1 ^ E2 ^E3). = P(E1 )P(E2 ) + P(E1 )P(E3 )+P(E2 )P(E3 )-2P(E1 )P(E2)P(E3) +[P(E1 ^ E2 ) - P(E1 )P(E2 )] +[P(E1 ^ E3 ) - P(E1 )P(E3 )] +[P(E2 ^ E3 ) - P(E2 )P(E3 )] -2[P(E1 ^ E2 ^ E3 ) - P(E1 ) P(E2 )P(E3 )] - P(E1 ^ E2 ^ E3 ) < P(Ei ^ Ej ) therefore P(Ei ^ Ej ) < Paye

  18. Danger Of Extrapolation to the Ultra reliability Region Example1: E1 = E2 = E3 = 10-5 If independent then p(Ei^Ej) = 10-10 -If p(Ei^Ej) = 10-7/hour one could test for a 100 years and not seen even one coincident error. Example2: E1 = E2 = E3 = 10-4 -If p(Ei^Ej) = 10-4 /hour one could test for a one years and not likely see even one coincident error!!

  19. -In the second case if the erroneous assumption of independence would be made then it would allow the assignment of a 3*10-8 probability of failure to the system when in reality the system is no better than 10-5 . -In order to get probability of failure to be less than 10-9 at 1 hour we need p(Ei^Ej) to be less then 10-12

  20. Feasibility of a General Model For Coincident Errors There are two kinds of models: • The model includes terms which cannot be measured within feasible amounts of time. • The model includes only parameters which can be measured within feasible amounts of time. -A general model must provide a mechanism that makes the interaction terms negligibly small. - There is little hope of deriving the interaction terms from fundamental Laws, since the error process occurs in the human mind.

  21. The Coincident-Error Experiments Experiment that was performed by Knight and Leveson: -27 versions of a program were produced and subjected to 1,000,000 input cases. -The observed average failure rate per input was 0.0007. -independence model was rejected. -In order to observe the errors the error rate must be in the low to moderate reliability region. Future experiments will have one of the following results :

  22. Demonstration that the independence assumption does not hold for the low reliability system • 2. Demonstration that the independence assumption does hold from systems for the low reliability system. • 3. No coincident errors were seen but the test time was insufficient to demonstrate independence for the potentially ultra reliable system.

  23. Conclusions • The potential performance advantages of using computers over their analog predecessors have created an atmosphere where serious safety concerns about digital hardware and software are not adequately addressed. • Practical methods to prevent design errors have not been found.

  24. Life testing of ultra reliable software is infeasible . • (i.e. to quantify 10-8 /hour failure rate requires more than 108 hours o testing). • The assumption of independence is not reasonable for software and can not be tested for software or for hardware in the ultra reliable region. • It is possible that models which are inferior to other models in the moderate region are superior in the ultra reliable region – but this cannot be demonstrated.

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