2009-02-14 00:42:34 +00:00
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#! /usr/bin/python
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2020-09-11 14:28:22 +00:00
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from __future__ import print_function
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2009-02-14 00:42:34 +00:00
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import math
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from allmydata.util import statistics
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2009-02-19 20:55:15 +00:00
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from numpy import array, matrix, dot
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2009-02-14 00:42:34 +00:00
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DAY=24*60*60
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MONTH=31*DAY
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YEAR=365*DAY
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2019-05-15 06:17:44 +00:00
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class ReliabilityModel(object):
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2009-02-14 00:42:34 +00:00
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"""Generate a model of system-wide reliability, given several input
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parameters.
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This runs a simulation in which time is quantized down to 'delta' seconds
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(default is one month): a smaller delta will result in a more accurate
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simulation, but will take longer to run. 'report_span' simulated seconds
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will be run.
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The encoding parameters are provided as 'k' (minimum number of shares
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needed to recover the file) and 'N' (total number of shares generated).
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The default parameters are 3-of-10.
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The first step is to build a probability of individual drive loss during
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any given delta. This uses a simple exponential model, in which the
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average drive lifetime is specified by the 'drive_lifetime' parameter
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(default is 8 years).
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The second step is to calculate a 'transition matrix': a table of
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probabilities that shows, given A shares at the start of the delta, what
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the chances are of having B shares left at the end of the delta. The
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current code optimistically assumes all drives are independent. A
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subclass could override that assumption.
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An additional 'repair matrix' is created to show what happens when the
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Checker/Repairer is run. In the simulation, the Checker will be run every
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'check_period' seconds (default is one month), and the Repairer will be
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run if it sees fewer than 'R' shares (default 7).
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The third step is to finally run the simulation. An initial probability
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vector is created (with a 100% chance of N shares and a 0% chance of
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fewer than N shares), then it is multiplied by the transition matrix for
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every delta of time. Each time the Checker is to be run, the repair
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matrix is multiplied in, and some additional stats are accumulated
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(average number of repairs that occur, average number of shares
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regenerated per repair).
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The output is a ReliabilityReport instance, which contains a table that
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samples the state of the simulation once each 'report_period' seconds
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(defaults to 3 months). Each row of this table will contain the
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probability vector for one sample period (chance of having X shares, from
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0 to N, at the end of the period). The report will also contain other
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information.
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"""
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@classmethod
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def run(klass,
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drive_lifetime=8*YEAR,
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k=3, R=7, N=10,
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delta=1*MONTH,
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check_period=1*MONTH,
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report_period=3*MONTH,
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report_span=5*YEAR,
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):
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self = klass()
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check_period = check_period-1
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P = self.p_in_period(drive_lifetime, delta)
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decay = self.build_decay_matrix(N, P)
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repair = self.build_repair_matrix(k, N, R)
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2020-09-11 14:28:22 +00:00
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#print("DECAY:", decay)
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#print("OLD-POST-REPAIR:", old_post_repair)
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#print("NEW-POST-REPAIR:", decay * repair)
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#print("REPAIR:", repair)
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#print("DIFF:", (old_post_repair - decay * repair))
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2009-02-19 20:55:15 +00:00
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START = array([0]*N + [1])
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DEAD = array([1]*k + [0]*(1+N-k))
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REPAIRp = array([0]*k + [1]*(R-k) + [0]*(1+N-R))
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REPAIR_newshares = array([0]*k +
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[N-i for i in range(k, R)] +
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[0]*(1+N-R))
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assert REPAIR_newshares.shape[0] == N+1
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#print("START", START)
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#print("REPAIRp", REPAIRp)
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#print("REPAIR_newshares", REPAIR_newshares)
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unmaintained_state = START
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maintained_state = START
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last_check = 0
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last_report = 0
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P_repaired_last_check_period = 0.0
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needed_repairs = []
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needed_new_shares = []
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report = ReliabilityReport()
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for t in range(0, report_span+delta, delta):
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# the .A[0] turns the one-row matrix back into an array
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unmaintained_state = (unmaintained_state * decay).A[0]
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maintained_state = (maintained_state * decay).A[0]
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if (t-last_check) > check_period:
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last_check = t
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# we do a check-and-repair this frequently
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need_repair = dot(maintained_state, REPAIRp)
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P_repaired_last_check_period = need_repair
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new_shares = dot(maintained_state, REPAIR_newshares)
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needed_repairs.append(need_repair)
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needed_new_shares.append(new_shares)
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maintained_state = (maintained_state * repair).A[0]
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if (t-last_report) > report_period:
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last_report = t
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P_dead_unmaintained = dot(unmaintained_state, DEAD)
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P_dead_maintained = dot(maintained_state, DEAD)
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cumulative_number_of_repairs = sum(needed_repairs)
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cumulative_number_of_new_shares = sum(needed_new_shares)
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report.add_sample(t, unmaintained_state, maintained_state,
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P_repaired_last_check_period,
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cumulative_number_of_repairs,
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cumulative_number_of_new_shares,
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P_dead_unmaintained, P_dead_maintained)
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# record one more sample at the end of the run
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P_dead_unmaintained = dot(unmaintained_state, DEAD)
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P_dead_maintained = dot(maintained_state, DEAD)
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cumulative_number_of_repairs = sum(needed_repairs)
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cumulative_number_of_new_shares = sum(needed_new_shares)
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report.add_sample(t, unmaintained_state, maintained_state,
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P_repaired_last_check_period,
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cumulative_number_of_repairs,
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cumulative_number_of_new_shares,
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P_dead_unmaintained, P_dead_maintained)
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2009-02-15 23:24:51 +00:00
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#def yandm(seconds):
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# return "%dy.%dm" % (int(seconds/YEAR), int( (seconds%YEAR)/MONTH))
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#needed_repairs_total = sum(needed_repairs)
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#needed_new_shares_total = sum(needed_new_shares)
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#print("at 2y:")
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#print(" unmaintained", unmaintained_state)
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#print(" maintained", maintained_state)
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#print(" number of repairs", needed_repairs_total)
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#print(" new shares generated", needed_new_shares_total)
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#repair_rate_inv = report_span / needed_repairs_total
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#print(" avg repair rate: once every %s" % yandm(repair_rate_inv))
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#print(" avg repair download: one share every %s" % yandm(repair_rate_inv/k))
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#print(" avg repair upload: one share every %s" % yandm(report_span / needed_new_shares_total))
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return report
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def p_in_period(self, avg_lifetime, period):
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"""Given an average lifetime of a disk (using an exponential model),
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what is the chance that a live disk will survive the next 'period'
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seconds?"""
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# eg p_in_period(8*YEAR, MONTH) = 98.94%
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return math.exp(-1.0*period/avg_lifetime)
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def build_decay_matrix(self, N, P):
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"""Return a decay matrix. decay[start_shares][end_shares] is the
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conditional probability of finishing with end_shares, given that we
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started with start_shares."""
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decay_rows = []
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decay_rows.append( [0.0]*(N+1) )
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for start_shares in range(1, (N+1)):
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end_shares = self.build_decay_row(start_shares, P)
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decay_row = end_shares + [0.0] * (N-start_shares)
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assert len(decay_row) == (N+1), len(decay_row)
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decay_rows.append(decay_row)
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decay = matrix(decay_rows)
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return decay
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def build_decay_row(self, start_shares, P):
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"""Return a decay row 'end_shares'. end_shares[i] is the chance that
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we finish with i shares, given that we started with start_shares, for
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all i between 0 and start_shares, inclusive. This implementation
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assumes that all shares are independent (IID), but a more complex
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model could incorporate inter-share failure correlations like having
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two shares on the same server."""
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end_shares = statistics.binomial_distribution_pmf(start_shares, P)
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return end_shares
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def build_repair_matrix(self, k, N, R):
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"""Return a repair matrix. repair[start][end]: is the conditional
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probability of the repairer finishing with 'end' shares, given that
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it began with 'start' shares (repair if fewer than R shares). The
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repairer's behavior is deterministic, so all values in this matrix
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are either 0 or 1. This matrix should be applied *after* the decay
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matrix."""
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new_repair_rows = []
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for start_shares in range(0, N+1):
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new_repair_row = [0] * (N+1)
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if start_shares < k:
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new_repair_row[start_shares] = 1
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elif start_shares < R:
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new_repair_row[N] = 1
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else:
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new_repair_row[start_shares] = 1
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new_repair_rows.append(new_repair_row)
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repair = matrix(new_repair_rows)
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return repair
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2019-05-15 06:17:44 +00:00
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class ReliabilityReport(object):
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def __init__(self):
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self.samples = []
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def add_sample(self, when, unmaintained_shareprobs, maintained_shareprobs,
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P_repaired_last_check_period,
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cumulative_number_of_repairs,
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cumulative_number_of_new_shares,
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P_dead_unmaintained, P_dead_maintained):
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"""
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when: the timestamp at the end of the report period
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unmaintained_shareprobs: a vector of probabilities, element[S]
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is the chance that there are S shares
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left at the end of the report period.
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This tracks what happens if no repair
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is ever done.
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maintained_shareprobs: same, but for 'maintained' grids, where
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check and repair is done at the end
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of each check period
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P_repaired_last_check_period: a float, with the probability
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that a repair was performed
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at the end of the most recent
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check period.
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cumulative_number_of_repairs: a float, with the average number
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of repairs that will have been
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performed by the end of the
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report period
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cumulative_number_of_new_shares: a float, with the average number
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of new shares that repair proceses
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generated by the end of the report
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period
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P_dead_unmaintained: a float, with the chance that the file will
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be unrecoverable at the end of the period
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P_dead_maintained: same, but for maintained grids
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"""
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row = (when, unmaintained_shareprobs, maintained_shareprobs,
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P_repaired_last_check_period,
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cumulative_number_of_repairs,
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cumulative_number_of_new_shares,
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P_dead_unmaintained, P_dead_maintained)
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self.samples.append(row)
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