1*33de042dSApple OSS Distributions#!/usr/bin/env python3 2*33de042dSApple OSS Distributions 3*33de042dSApple OSS Distributionsfrom fractions import Fraction 4*33de042dSApple OSS Distributionsfrom math import ceil 5*33de042dSApple OSS Distributionsfrom math import comb 6*33de042dSApple OSS Distributions 7*33de042dSApple OSS Distributions 8*33de042dSApple OSS Distributions# The inverse of 2, i.e. 2^-1. To be used as a base in exponentiations 9*33de042dSApple OSS Distributions# representing probabilities. 10*33de042dSApple OSS DistributionsINV2 = Fraction(1, 2) 11*33de042dSApple OSS Distributions 12*33de042dSApple OSS Distributions 13*33de042dSApple OSS Distributions# The probability of a false positive health test failure expressed as 14*33de042dSApple OSS Distributions# the negative logarithm of the *actual* probability. In simpler 15*33de042dSApple OSS Distributions# terms, the actual probability is: 16*33de042dSApple OSS Distributions# 17*33de042dSApple OSS Distributions# INV2 ** A 18*33de042dSApple OSS Distributions# 19*33de042dSApple OSS Distributions# It is simpler to keep this representation when computing the bound 20*33de042dSApple OSS Distributions# of the Repetition Count Test (below). 21*33de042dSApple OSS DistributionsA = 40 22*33de042dSApple OSS Distributions 23*33de042dSApple OSS Distributions 24*33de042dSApple OSS Distributions# The estimated min-entropy per sample in bits. Min-entropy is the 25*33de042dSApple OSS Distributions# negative logarithm of the probability of the *most likely* outcome. 26*33de042dSApple OSS Distributions# 27*33de042dSApple OSS Distributions# We consider this estimate to be conservative. 28*33de042dSApple OSS DistributionsH = 1 29*33de042dSApple OSS Distributions 30*33de042dSApple OSS Distributions 31*33de042dSApple OSS Distributions# The probability of the most likely outcome occurring in a given 32*33de042dSApple OSS Distributions# sample. This derives from the definition of min-entropy (see above). 33*33de042dSApple OSS DistributionsP = INV2 ** H 34*33de042dSApple OSS Distributions 35*33de042dSApple OSS Distributions 36*33de042dSApple OSS Distributions# 4.4.1 Repetition Count Test 37*33de042dSApple OSS Distributions# 38*33de042dSApple OSS Distributions# The Repetition Count Test (RCT) detects catastrophic failures in the 39*33de042dSApple OSS Distributions# noise source when it becomes "stuck" generating a single value over 40*33de042dSApple OSS Distributions# many consecutive samples. 41*33de042dSApple OSS Distributions# 42*33de042dSApple OSS Distributions# The probability of generating C consecutive identical samples is: 43*33de042dSApple OSS Distributions# 44*33de042dSApple OSS Distributions# P^(C-1) 45*33de042dSApple OSS Distributions# 46*33de042dSApple OSS Distributions# Or equivalently: 47*33de042dSApple OSS Distributions# 48*33de042dSApple OSS Distributions# 2^(-H * (C-1)) 49*33de042dSApple OSS Distributions# 50*33de042dSApple OSS Distributions# To keep this under our rate of acceptable false positives, we need 51*33de042dSApple OSS Distributions# to satisfy this inequality: 52*33de042dSApple OSS Distributions# 53*33de042dSApple OSS Distributions# 2^-A >= 2^(-H * (C-1)) 54*33de042dSApple OSS Distributions# 55*33de042dSApple OSS Distributions# Taking the logarithm of both sides, we have: 56*33de042dSApple OSS Distributions# 57*33de042dSApple OSS Distributions# -A >= -H * (C-1) 58*33de042dSApple OSS Distributions# 59*33de042dSApple OSS Distributions# Solving for C, we have: 60*33de042dSApple OSS Distributions# 61*33de042dSApple OSS Distributions# (A / H) + 1 >= C 62*33de042dSApple OSS Distributionsdef repetition_count_bound(): 63*33de042dSApple OSS Distributions return 1 + ceil(Fraction(A, H)) 64*33de042dSApple OSS Distributions 65*33de042dSApple OSS Distributions 66*33de042dSApple OSS Distributions# 4.4.2 Adaptive Proportion Test 67*33de042dSApple OSS Distributions# 68*33de042dSApple OSS Distributions# The Adaptive Proportion Test (APT) tries to detect more subtle noise 69*33de042dSApple OSS Distributions# source failures causing certain values to occur with unexpected 70*33de042dSApple OSS Distributions# frequency. It does this by taking a sample from the noise source and 71*33de042dSApple OSS Distributions# counting how many times the same sample occurs within a fixed-size 72*33de042dSApple OSS Distributions# window. 73*33de042dSApple OSS Distributions 74*33de042dSApple OSS Distributions 75*33de042dSApple OSS Distributions# The size of the window for non-binary alphabets for the APT. 76*33de042dSApple OSS DistributionsW = 512 77*33de042dSApple OSS Distributions 78*33de042dSApple OSS Distributions 79*33de042dSApple OSS Distributions# The probability mass function measuring the probability of exactly k 80*33de042dSApple OSS Distributions# occurrences of a given value within the observation window of size 81*33de042dSApple OSS Distributions# W. We use the probability of the most likely event (as above). 82*33de042dSApple OSS Distributions# 83*33de042dSApple OSS Distributions# There are three terms: 84*33de042dSApple OSS Distributions# 85*33de042dSApple OSS Distributions# 1. The binomial coefficient of k, i.e. W-choose-k. Simply, how many 86*33de042dSApple OSS Distributions# ways are there to get exactly k outcomes given W chances. 87*33de042dSApple OSS Distributions# 88*33de042dSApple OSS Distributions# 2. The probability of each of those k events occurring. 89*33de042dSApple OSS Distributions# 90*33de042dSApple OSS Distributions# 3. The probability that the other W-k events have some other 91*33de042dSApple OSS Distributions# outcome. 92*33de042dSApple OSS Distributionsdef pmf(k): 93*33de042dSApple OSS Distributions return comb(W, k) * P**k * (1 - P)**(W-k) 94*33de042dSApple OSS Distributions 95*33de042dSApple OSS Distributions 96*33de042dSApple OSS Distributions# The sum of probabilties of all possible counts of occurrences is 1. 97*33de042dSApple OSS Distributionsassert sum(map(pmf, range(W+1))) == 1 98*33de042dSApple OSS Distributions 99*33de042dSApple OSS Distributions 100*33de042dSApple OSS Distributions# We want to find the minimal count of occurrences such that the 101*33de042dSApple OSS Distributions# cumulative probability of seeing *at least* that count of 102*33de042dSApple OSS Distributions# occurrences (but possibly more) is no more than our false 103*33de042dSApple OSS Distributions# positive threshold. 104*33de042dSApple OSS Distributionsdef adaptive_proportion_bound(): 105*33de042dSApple OSS Distributions # The list of probabilities for each of the possible counts of 106*33de042dSApple OSS Distributions # occurrences. 107*33de042dSApple OSS Distributions probs = [pmf(x) for x in range(W+1)] 108*33de042dSApple OSS Distributions 109*33de042dSApple OSS Distributions # The list of cumulative distributions for each of the possible 110*33de042dSApple OSS Distributions # counts of occurrences. 111*33de042dSApple OSS Distributions # 112*33de042dSApple OSS Distributions # Whereas probs is a list of probabilities of *exactly* k 113*33de042dSApple OSS Distributions # occurrences, this is a list of probabilities of *k or more* 114*33de042dSApple OSS Distributions # occurrences. 115*33de042dSApple OSS Distributions # 116*33de042dSApple OSS Distributions # These are just sums of probabilities across a range of counts. 117*33de042dSApple OSS Distributions dists = [sum(probs[x:]) for x in range(W+1)] 118*33de042dSApple OSS Distributions 119*33de042dSApple OSS Distributions # Because we have constructed dists as an ordered list of 120*33de042dSApple OSS Distributions # cumulative probabilities, we can simply return the index of the 121*33de042dSApple OSS Distributions # first value that is below our threshold. 122*33de042dSApple OSS Distributions for i, d in enumerate(dists): 123*33de042dSApple OSS Distributions if d <= INV2**A: 124*33de042dSApple OSS Distributions return i 125*33de042dSApple OSS Distributions 126*33de042dSApple OSS Distributions 127*33de042dSApple OSS Distributionsdef main(): 128*33de042dSApple OSS Distributions print('Estimated min-entropy:', H) 129*33de042dSApple OSS Distributions print('False positive rate: 2^-{}'.format(A)) 130*33de042dSApple OSS Distributions print('Repetition Count Test bound:', repetition_count_bound()) 131*33de042dSApple OSS Distributions print('Adaptive Proportion Test bound:', adaptive_proportion_bound()) 132*33de042dSApple OSS Distributions 133*33de042dSApple OSS Distributions 134*33de042dSApple OSS Distributionsif __name__ == '__main__': 135*33de042dSApple OSS Distributions main() 136