Fully Homomorphic Encryption without Modulus Switching

This scheme proposed by Brakerski ^[1] has a number of advantages over previous candidates such as BGV. In particular, it uses the same modulus throughout the evaluation process, so there's no need for modulus switching. Security of these scheme is baed on the hardness of the GapSVP problem.

Preliminaries

For an integer ${\displaystyle q}$, write ${\displaystyle \mathbb {Z} _{q}:=\left(-q/2,q/2\right]\cap \mathbb {Z} }$. This is not the same with the ring ${\displaystyle \mathbb {Z} /q\mathbb {Z} }$. For any ${\displaystyle x\in \mathbb {Q} }$, write ${\displaystyle [x]_{p}}$ for the unique value in ${\displaystyle \left(-q/2,q/2\right]\cap \mathbb {Z} }$ that is congruent to ${\displaystyle x}$ modulo ${\displaystyle q}$.

If ${\displaystyle v,w}$ are two ${\displaystyle n}$-dimensional vectors, then the tensor product ${\displaystyle v\otimes w}$ is the ${\displaystyle n^{2}}$ dimensional vector containing all elements of the form ${\displaystyle v[i]w[j]}$. Note that

${\displaystyle <v\otimes w,x\otimes y>=<v,x>\cdot <w,y>.}$

Building Blocks of a homomorphic encryption scheme

We start by presenting Regev's ^[2] basic public-key encryption scheme.

The Regev scheme

Let ${\displaystyle q=q(n)}$ be an integer function and let ${\displaystyle \chi (n)}$ be a distribution over ${\displaystyle \mathbb {Z} }$. The scheme 'Regev' is defined as follows:

• Regev.SecretKeygen( ${\displaystyle 1^{n}}$ ): Sample ${\displaystyle s\leftarrow \mathbb {Z} _{q}^{n}}$ uniformly. Output ${\displaystyle sk=s}$.

• Regev.PublicKeygen(${\displaystyle s}$): Let ${\displaystyle N:=(n+1)(\log q+O(1))}$. Sample uniformly ${\displaystyle A\leftarrow \mathbb {Z} _{q}^{N\times n}}$ then sample ${\displaystyle e\leftarrow \chi ^{N}}$. Compute ${\displaystyle b:=[A\cdot s+e]_{q}}$. Here we apply ${\displaystyle [\cdot ]_{q}}$ to every entry in the ${\displaystyle N}$-dimensional vector ${\displaystyle A\cdot s+e}$ and define

${\displaystyle P:=[b\vert -A]\in \mathbb {Z} _{q}^{N\times (n+1)}}$.

Output ${\displaystyle pk=P}$.

• Regev.Enc(${\displaystyle pk,m}$): To encrypt a message ${\displaystyle m\in \{0,1\}}$ using ${\displaystyle pk=P}$, sample ${\displaystyle r\in \{0,1\}^{N}}$ uniformly and output the ciphertext

${\displaystyle c:=\left[P^{T}\cdot r+\left\lfloor {\frac {q}{2}}\right\rfloor \cdot {\hat {m}}\right]_{q}\in \mathbb {Z} _{q}^{n+1},}$

where ${\displaystyle {\hat {m}}:=(m,0,\dots ,0)\in \{0,1\}^{n+1}}$.

• Regev.Dec(${\displaystyle sk,c}$): To decrypt ${\displaystyle c\in \mathbb {Z} _{q}^{n+1}}$ using the secret key ${\displaystyle sk=s}$, compute

${\displaystyle m:=\left[\left\lfloor 2\cdot {\frac {[<c,(1,2)>]_{q}}{q}}\right\rceil \right]_{2}.}$

In order to prove corectness, the author first shows (Lemma 3.1 in [1]) that if ${\displaystyle q,n,N}$ and ${\displaystyle \chi }$- ${\displaystyle B}$-bounded are parameters for the 'Regev' scheme described above and if ${\displaystyle c}$ is the fresh encryption of some message ${\displaystyle m\in \{0,1\}}$, then

${\displaystyle <c,(1,s)>=\left\lfloor {\frac {q}{2}}\right\rfloor \cdot m+e}$

for some ${\displaystyle e}$ with ${\displaystyle |e|\leq N\cdot B}$.

Then, Lemma 3.2 in the same article asserts that if ${\displaystyle s\in \mathbb {Z} ^{n}}$ is some vector and ${\displaystyle c\in \mathbb {Z} _{q}^{n+1}}$ is such that

${\displaystyle <c,(1,s)>=\left\lfloor {\frac {q}{2}}\right\rfloor \cdot m+e}$

with ${\displaystyle m\in \{0,1\}}$ and ${\displaystyle |e|<\lfloor q/2\rfloor /2}$, then

Regev.Dec(${\displaystyle s,c}$ )= ${\displaystyle m}$ .

Brakerski claims that the security of this scheme reduces to the hardness of (a decisional variant of) LWE problem by classical arguments (originally due to Regev [2]).

Vector decompositions

Recall from BGV the procedures

${\displaystyle BitDecomp_{q}(x):\mathbb {Z} ^{n}\to \{0,1\}^{n\cdot \lceil \log q\rceil }}$

and

${\displaystyle PowersOfTwo_{q}(y):\mathbb {Z} ^{n}\to \mathbb {Z} _{q}^{n\cdot \lceil \log q\rceil }.}$

When the modulus ${\displaystyle q}$ is clear from the context we will omit its writing.

We also recall the property

${\displaystyle <x,y>=<BitDecomp_{q}(x),PowersOfTwo_{q}(y)>{\pmod {q}}}$.

Key switching

In the functions described below ${\displaystyle q}$ is an integer and ${\displaystyle \chi }$ is a distribution over ${\displaystyle \mathbb {Z} }$.

• ${\displaystyle SwitchKeyGen_{q,\chi }(s,t}$): For a 'source' key ${\displaystyle s\in \mathbb {Z} ^{n_{s}}}$ and target key ${\displaystyle t\in \mathbb {Z} ^{n_{t}}}$ this outputs matrix with ${\displaystyle n_{s}\cdot \lceil \log q\rceil }$ rows and ${\displaystyle (n_{t}+1)}$ columns, very similar to an encryption of ${\displaystyle PowersOfTwo_{q}(s)}$ under the secret key ${\displaystyle t}$. Let us call this matrix ${\displaystyle P_{s:t}}$.

• ${\displaystyle SwithcKey_{q}(P_{s:t},c_{s})}$: To switch a ciphertext from a secret key ${\displaystyle s}$ to ${\displaystyle (1,t)}$, output

${\displaystyle c_{t}:=[P_{s:t}^{T}\cdot BitDecomp_{q}(c_{s})]_{q}}$.

Details on the correctness and security of this scheme are given at the end of Section 3 in [1].

A scale Invariant Homomorphic Encryption Scheme

Let ${\displaystyle q=q(n)}$ be an integer function, ${\displaystyle L=L(n)}$ a polynomial and $\chi= \chi(n)$ a distribution over the integers. The SI-HE scheme is defined as follows:

• SI-HE.Keygen(${\displaystyle 1^{L},1^{n}}$): Sample ${\displaystyle L+1}$ vectors ${\displaystyle s_{0},\dots ,s_{L}\leftarrow }$ Regev.SecretKeygen(${\displaystyle 1^{n}}$ ) and generate a Regev public key for the first one: ${\displaystyle P_{0}\leftarrow Regev.PublicKeygen(s_{0})}$. For all ${\displaystyle i\in [L]}$, define

${\displaystyle {\tilde {s_{i-1}}}:=BitDecomp((1,s_{i-1}))\otimes BitDecomp((1,s_{i-1}))\in \{0,1\}^{((n+1)\lceil \log q\rceil )^{2}}}$

and compute

${\displaystyle P_{(i-1):i}\leftarrow SwitchKeyGen({\tilde {s_{i-1}}},s_{i})}$ .

Output ${\displaystyle pk:=P_{0}}$ and ${\displaystyle evk=\{P_{(i-1):i}:i\in [L]\}}$ and ${\displaystyle sk=s_{L}}$.

• SI-HE.Enc(${\displaystyle pk,m}$): This is identical to Regev's. Just output ${\displaystyle c\leftarrow Regev.Enc(pk,m)}$.

• SI-HE.Eval(${\displaystyle evk}$): Here we describe homomorphic addition and multiplication over the field with two elements, operations that allow the evaluation of depth ${\displaystyle L}$ arithmetic circuits in a gate-by-gate manner. The convention for a gate at level ${\displaystyle i}$ of the circuit is that the operand ciphertexts are decryptable using ${\displaystyle s_{i-1}}$, and the output of the homomorphic operation is decryptable using ${\displaystyle s_{i}}$.

References