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Kirill Smelkov
git-backup
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7fcb8c67
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7fcb8c67
authored
Apr 18, 2016
by
Kirill Smelkov
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My notes on algorithmical restore optimization
when/if we ever get to need them.
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============================================================
Notes on how to restore objects in optimal size & time way
============================================================
A, B, C - set of objects belonging to repository A, B, C,...
M - set of objects from all repositories
∀ A A ∪ !A = M M = A ∪ B ∪ C ∪ ...
∀ B B ∩ M = B
↓
B = B∩(A∪!A) = B∩A ∪ B∩!A
A B C D E F ...
A -> 1A ∀ obj ∈ A, D, F ... => obj -> 1 0 0 1 0 1 ...
!A -> 0A ∉ B, C, E ... ↓
A∩!B∩!C∩ D∩!E∩ F ...
2^N
-> M = ⊕ bin(i)
i=0
bin(i) = ∩ (A or !A depending on bit in number i)
bin(i) ∩ bin(j) = ø (i != j)
bin(i) -- too much different sets - 2^N.
approximation:
M = ⋃ μi μi ∩ μj != ø (not necessarily)
⋯
N(M) ≤ ∑ N(μi)
⋯
min ∑ N(μi) = N(M) <=> μi = bin(i)
⋯
↓
we search minimum by ∇⋃μi
⋯
∢ (μi, μj) pair:
for it we have:
N(μi) + N(μj) in ∑ N(μ.)
⋯
μi ∪ μj in ⋃ μ.
⋯
if we split
μi, μj → μi∩!μj, μj∩!μi, μi∩μj
gradient is
∇ij ⋃μ. = -N(μi∩μj)
⋯
( proof:
A∪B = A∩!B ∪ B∩!A ∪ A∩B
N(A) = N(A∩(B∪!B)) = N(A∩B) + N(A∩!B)
N(B) = ... = N(A∩B) + N(B∩!A)
-> N(A)+N(B) = N(A∩!B) + N(B∩!A) + 2⋅N(A∩B)
but after splitting A,B we have
N(A∩!B) + N(B∩!A) + 1⋅N(A∩B)
so the delta is -N(A∩B).
now A=μi, B=μj )
↓
we find i,j for which N(μi∩μj) is max and split that pair. Then algorithm
continues. The algorithm is greedy - it can find minimum, but instead of global
a local one. We have a way to control how far absolute minimum is away
(comparing to N(M))
TODO Comparing N(μi∩μj) is O(n^2) -> heuristics to limit to O(n)
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