Locally recoverable code

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Locally recoverable codes are a family of error correction codes that were introduced first by D. S. Papailiopoulos and A. G. Dimakis^[1] and have been widely studied in information theory due to their applications related to distributive and cloud storage systems.^[2][3][4][5]

An ${\displaystyle [n,k,d,r]_{q}}$ LRC is an ${\displaystyle [n,k,d]_{q}}$ linear code such that there is a function ${\displaystyle f_{i}}$ that takes as input ${\displaystyle i}$ and a set of ${\displaystyle r}$ other coordinates of a codeword ${\displaystyle c=(c_{1},\ldots ,c_{n})\in C}$ different from ${\displaystyle c_{i}}$, and outputs ${\displaystyle c_{i}}$.

Let ${\displaystyle C}$ be a ${\displaystyle [n,k,d]_{q}}$ linear code. For ${\displaystyle i\in \{1,\ldots ,n\}}$, let us denote by ${\displaystyle r_{i}}$ the minimum number of other coordinates we have to look at to recover an erasure in coordinate ${\displaystyle i}$. The number ${\displaystyle r_{i}}$ is said to be the locality of the ${\displaystyle i}$-th coordinate of the code. The locality of the code is defined as

${\displaystyle r={\textrm {max}}\{r_{i}|i\in \{1,\ldots ,n\}\}}$

An ${\displaystyle [n,k,d,r]_{q}}$ locally recoverable code (LRC) is an ${\displaystyle [n,k,d]_{q}}$ linear code ${\displaystyle C\in \mathbb {F} _{q}^{n}}$ with locality ${\displaystyle r}$.

Let ${\displaystyle C}$ be an ${\displaystyle [n,k,d]_{q}}$-locally recoverable code. Then an erased component can be recovered linearly,^[6] i.e. for every ${\displaystyle i\in \{1,\ldots ,n\}}$, the space of linear equations of the code contains elements of the form ${\displaystyle x_{i}=f(x_{i_{1}},\ldots ,x_{i_{r}})}$, where ${\displaystyle i_{j}\neq i}$.

Theorem^[7] Let ${\displaystyle n=(r+1)s}$ and let ${\displaystyle C}$ be an ${\displaystyle [n,k,d]_{q}}$-locally recoverable code having ${\displaystyle s}$ disjoint locality sets of size ${\displaystyle r+1}$. Then

${\displaystyle d\leq n-k-\left\lceil {\frac {k}{r}}\right\rceil +2}$

An ${\displaystyle [n,k,d,r]_{q}}$-LRC ${\displaystyle C}$ is said to be optimal if the minimum distance of ${\displaystyle C}$ satisfies

${\displaystyle d=n-k-\left\lceil {\frac {k}{r}}\right\rceil +2}$

Let ${\displaystyle f\in \mathbb {F} _{q}[x]}$ be a polynomial and let ${\displaystyle \ell }$ be a positive integer. Then ${\displaystyle f}$ is said to be (${\displaystyle r}$, ${\displaystyle \ell }$)-good if

• ${\displaystyle f}$ has degree ${\displaystyle r+1}$,

• there exist distinct subsets ${\displaystyle A_{1},\ldots ,A_{\ell }}$ of ${\displaystyle \mathbb {F} _{q}}$ such that

– for any ${\displaystyle i\in \{1,\ldots ,\ell \}}$, ${\displaystyle f(A_{i})=\{t_{i}\}}$ for some ${\displaystyle t_{i}\in \mathbb {F} _{q}}$ , i.e., ${\displaystyle f}$ is constant on ${\displaystyle A_{i}}$,

– ${\displaystyle \#A_{i}=r+1}$,

– ${\displaystyle A_{i}\cap A_{j}=\varnothing }$ for any ${\displaystyle i\neq j}$.

We say that {${\displaystyle A_{1},\ldots ,A_{\ell }}$} is a splitting covering for ${\displaystyle f}$.^[8]

The Tamo–Barg construction utilizes good polynomials.^[9]

• Suppose that a ${\displaystyle (r,\ell )}$-good polynomial ${\displaystyle f(x)}$ over ${\displaystyle \mathbb {F} _{q}}$ is given with splitting covering ${\displaystyle i\in \{1,\ldots ,\ell \}}$.

• Let ${\displaystyle s\leq \ell -1}$ be a positive integer.

• Consider the following ${\displaystyle \mathbb {F} _{q}}$-vector space of polynomials $${\displaystyle V=\{\sum _{i=0}^{s}g_{i}(x)f(x)^{i}:\deg(g_{i}(x))\leq \deg(f(x))-2\}.}$$

• Let ${\textstyle T=\bigcup _{i=1}^{\ell }A_{i}}$.

• The code ${\displaystyle \{ev_{T}(g):g\in V\}}$ is an ${\displaystyle ((r+1)\ell ,(s+1)r,d,r)}$-optimal locally coverable code, where ${\displaystyle ev_{T}}$ denotes evaluation of ${\displaystyle g}$ at all points in the set ${\displaystyle T}$.

• Length. The length is the number of evaluation points. Because the sets ${\displaystyle A_{i}}$ are disjoint for ${\displaystyle i\in \{1,\ldots ,\ell \}}$, the length of the code is ${\displaystyle |T|=(r+1)\ell }$.

• Dimension. The dimension of the code is ${\displaystyle (s+1)r}$, for ${\displaystyle s}$ ≤ ${\displaystyle \ell -1}$, as each ${\displaystyle g_{i}}$ has degree at most ${\displaystyle \deg(f(x))-2}$, covering a vector space of dimension ${\displaystyle \deg(f(x))-1=r}$, and by the construction of ${\displaystyle V}$, there are ${\displaystyle s+1}$ distinct ${\displaystyle g_{i}}$.

• Distance. The distance is given by the fact that ${\displaystyle V\subseteq \mathbb {F} _{q}[x]_{\leq k}}$, where ${\displaystyle k=r+1-2+s(r+1)}$, and the obtained code is the Reed-Solomon code of degree at most ${\displaystyle k}$, so the minimum distance equals ${\displaystyle (r+1)\ell -((r+1)-2+s(r+1))}$.

• Locality. After the erasure of the single component, the evaluation at ${\displaystyle a_{i}\in A_{i}}$, where ${\displaystyle |A_{i}|=r+1}$, is unknown, but the evaluations for all other ${\displaystyle a\in A_{i}}$ are known, so at most ${\displaystyle r}$ evaluations are needed to uniquely determine the erased component, which gives us the locality of ${\displaystyle r}$.

To see this, ${\displaystyle g}$ restricted to ${\displaystyle A_{j}}$ can be described by a polynomial ${\displaystyle h}$ of degree at most Failed to parse (syntax error): {\displaystyle \deg}(f(x))-2 = r + 1 - 2 = r - 1} thanks to the form of the elements in ${\displaystyle V}$ (i.e., thanks to the fact that ${\displaystyle f}$ is constant on ${\displaystyle A_{j}}$, and the ${\displaystyle g_{i}}$'s have degree at most ${\displaystyle \deg(f(x))-2}$). On the other hand ${\displaystyle |A_{j}\backslash \{a_{j}\}|=r}$, and ${\displaystyle r}$ evaluations uniquely determine a polynomial of degree ${\displaystyle r-1}$. Therefore ${\displaystyle h}$ can be constructed and evaluated at ${\displaystyle a_{j}}$ to recover ${\displaystyle g(a_{j})}$.

We will use ${\displaystyle x^{5}\in \mathbb {F} _{41}[x]}$ to construct ${\displaystyle [15,8,6,4]}$-LRC. Notice that the degree of this polynomial is 5, and it is constant on ${\displaystyle A_{i}}$ for ${\displaystyle i\in \{1,\ldots ,8\}}$, where ${\displaystyle A_{1}=\{1,10,16,18,37\}}$, ${\displaystyle A_{2}=2A_{1}}$, ${\displaystyle A_{3}=3A_{1}}$, ${\displaystyle A_{4}=4A_{1}}$, ${\displaystyle A_{5}=5A_{1}}$, ${\displaystyle A_{6}=6A_{1}}$, ${\displaystyle A_{7}=11A_{1}}$, and ${\displaystyle A_{8}=15A_{1}}$: ${\displaystyle A_{1}^{5}=\{1\}}$, ${\displaystyle A_{2}^{5}=\{32\}}$, ${\displaystyle A_{3}^{5}=\{38\}}$, ${\displaystyle A_{4}^{5}=\{40\}}$, ${\displaystyle A_{5}^{5}=\{9\}}$, ${\displaystyle A_{6}^{5}=\{27\}}$, ${\displaystyle A_{7}^{5}=\{3\}}$, ${\displaystyle A_{8}^{5}=\{14\}}$. Hence, ${\displaystyle x^{5}}$ is a ${\displaystyle (4,8)}$-good polynomial over ${\displaystyle \mathbb {F} _{41}}$ by the definition. Now, we will use this polynomial to construct a code of dimension ${\displaystyle k=8}$ and length ${\displaystyle n=15}$ over ${\displaystyle \mathbb {F} _{41}}$. The locality of this code is 4, which will allow us to recover a single server failure by looking at the information contained in at most 4 other servers.

Next, let us define the encoding polynomial: ${\displaystyle f_{a}(x)=\sum _{i=0}^{r-1}f_{i}(x)x^{i}}$, where ${\displaystyle f_{i}(x)=\sum _{i=0}^{{\frac {k}{r}}-1}a_{i,j}g(x)^{j}}$. So, ${\displaystyle f_{a}(x)=}$ ${\displaystyle a_{0,0}+}$ ${\displaystyle a_{0,1}x^{5}+}$ ${\displaystyle a_{1,0}x+}$ ${\displaystyle a_{1,1}x^{6}+}$ ${\displaystyle a_{2,0}x^{2}+}$ ${\displaystyle a_{2,1}x^{7}+}$ ${\displaystyle a_{3,0}x^{3}+}$ ${\displaystyle a_{3,1}x^{8}}$.

Thus, we can use the obtained encoding polynomial if we take our data to encode as the row vector ${\displaystyle a=}$ ${\displaystyle (a_{0,0},a_{0,1},a_{1,0},a_{1,1},a_{2,0},a_{2,1},a_{3,0},a_{3,1})}$. Encoding the vector ${\displaystyle m}$ to a length 15 message vector ${\displaystyle c}$ by multiplying ${\displaystyle m}$ by the generator matrix

${\displaystyle G={\begin{pmatrix}1&1&1&1&1&1&1&1&1&1&1&1&1&1&1\\1&1&1&1&1&32&32&32&32&32&38&38&38&38&38\\1&10&16&18&37&2&20&32&33&36&3&7&13&29&30\\1&10&16&18&37&23&25&40&31&4&32&20&2&36&33\\1&18&10&37&16&4&31&40&23&25&9&8&5&21&39\\1&18&10&37&16&5&8&9&39&21&14&17&26&19&6\\1&16&37&10&18&8&5&9&21&39&27&15&24&35&22\\1&16&37&10&18&10&37&1&16&18&1&37&10&18&16\end{pmatrix}}}$

For example, the encoding of information vector ${\displaystyle m=(1,1,1,1,1,1,1,1)}$ gives the codeword ${\displaystyle c=mG=(8,8,5,9,21,3,36,31,32,12,2,20,37,33,21)}$.

Observe that we constructed an optimal LRC; therefore, using the Singleton bound, we have that the distance of this code is ${\displaystyle d=n-k-\left\lceil {\frac {k}{r}}\right\rceil +2=15-8-2+2=7}$. Thus, we can recover any 6 erasures from our codeword by looking at no more than 8 other components.

Definition^[10] A code ${\displaystyle C}$ has all-symbol locality ${\displaystyle r}$ and availability ${\displaystyle t}$ if every code symbol can be recovered from ${\displaystyle t}$ disjoint repair sets of other symbols, each set of size at most ${\displaystyle r}$ symbols. Such codes are called ${\displaystyle (r,t)_{a}}$-LRC.

Theorem^[11] The minimum distance of ${\displaystyle [n,k,d]_{q}}$-LRC having locality ${\displaystyle r}$ and availability ${\displaystyle t}$ satisfies the upper bound

${\displaystyle d\leq n-\sum _{i=0}^{t}\left\lfloor {\frac {k-1}{r^{i}}}\right\rfloor }$

.

If the code is systematic and locality and availability apply only to its information symbols, then the code has information locality ${\displaystyle r}$ and availability ${\displaystyle t}$, and is called ${\displaystyle (r,t)_{i}}$-LRC.

Theorem^[12] The minimum distance ${\displaystyle d}$ of an ${\displaystyle [n,k,d]_{q}}$ linear ${\displaystyle (r,t)_{i}}$-LRC satisfies the upper bound

${\displaystyle d\leq n-k-\left\lceil {\frac {t(k-1)+1}{t(r-1)+1}}\right\rceil +2}$

.