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math
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								\title{Sigma protocol and OR proofs - notes}

								\author{arnaucube}

								\date{March 2022}


								\begin{document}


								\maketitle


								\begin{abstract}

									This document contains the notes taken during the \emph{Cryptography Seminars} given by \href{https://github.com/rbkhmrcr}{Rebekah Mercer}.

								\end{abstract}


								\tableofcontents


								\section{Sigma protocol}


								\subsection{The protocol}

								Let $q$ be a prime, $q$ a prime divisor in $p-1$, and $g$ and element of order $q$ in $\mathbb{Z}_p^a$. Then we have $G = \langle g \rangle$.

								\\

								We assume that computationally for a given $A$ it's hard to find $a \in \mathbb{F}$ such that $A = g^a$.

								\\

								Alice wants to prove that knows the \emph{witness} $w \in \mathbb{F}$, such that the \emph{statement} $X = g^w$, without revealing $w$.


								\begin{enumerate}[1.]

									\item Alice generates a random $a \xleftarrow{r} \mathbb{F}$, and computes $A=g^a$. And sends $A$ to Bob.

									\item Bob generates a challenge $c \xleftarrow{r} \mathbb{F}$, and sends it to Alice.

									\item Alice computes $z=a + c \cdot w$, and sends it to Bob.

									\item Bob verifies it by checking that $g^z == X^c \cdot A$.

								\end{enumerate}


								We can unfold Bob's verification and see that:

								$$g^z == X^c \cdot A$$

								$$g^{a+cw} == g^{wc} g^a$$

								$$g^{a+cw} == g^{wc+a}$$


								\begin{center}

								\begin{sequencediagram}

								    \newinst[1]{a}{Alice}

								    \newinst[3]{b}{Bob}

								    \mess[0]{a}{$A$}{b}

								    \mess[2]{b}{$c$}{a}

								    \mess[2]{a}{$z$}{b}

								    \mess[0]{b}{$ok$}{a}

								\end{sequencediagram}

								\end{center}


								Properties:

								\begin{enumerate}[i.]

									\item \emph{correctness/completness}: if Alice know the witness for the statement, then they can create a valid proof.

									\item \emph{soundness}: if someone does not have knowledge of the witness, can not form a valid proof (verifier will always reject).

									\item \emph{zero knowledge}: nobody gains knowledge of anything new with the proof. prior knowledge + proof = prior knowledge

								\end{enumerate}


								\subsection{Non interactive protocol}

								With the \emph{Fiat-Shamir Heuristic}, we model a hash function as a random oracle, thus we can replace Bob's role by a hash function in order to obtain the challenge $c \in \mathbb{F}$.

								\\

								So, we replace the step 2 from the described protocol by $c = H(X || A)$ (where $H$ is a known hash function).


								\subsection{What could go wrong (Simulator)}

								If the verifier (Bob) sends $c \in \mathbb{F}$, prior to the prover committed to $A$, the prover could create a proof about a public key which they don't know $w$.

								\begin{enumerate}[1.]

									\item Bob sends $c \xleftarrow{r} \mathbb{F}$ to Alice

									\item Alice generates $z \xleftarrow{r} \mathbb{F}$

									\item Alice then computes $A = g^z X^{-c}$, and sends $z, A$ to Bob

									\item Bob would check that $g^z == X^c A$ and it would pass the verification, as $g^z== X^c \cdot A \Rightarrow g^z==X^c \cdot g^z X^{-c} \Rightarrow g^z == g^z$.

								\end{enumerate}


								As we've seen, it's really important the order of the steps, so Alice must commit to $A$ before knowing $c$.\\

								This 'fake' proof generation is often called the \emph{simulator} and used for further constructions.


								\section{OR proof}


								\emph{OR proofs} allows the prover to prove that they know the witness $w$ of one of the two known \emph{public keys} $X_0, X_1 \in \mathbb{F}$, without revealing which one. It uses the construction seen in the \emph{sigma protocols} together with the idea of the \emph{simulator}.


								A similar construction is used for $n$ statements in the \emph{ring signatures} scheme (used for example in \emph{Monero}). In our case, we will work with $n=2$.


								\subsection{The protocol}

								\subsubsection{Simulator}

								We can assume that the simulator is a box that for given the inputs $(g, X)$, it will output $(A_s, c_s, z_s)$, such that verification succeeds ($g^{z_s}==X^{c_s} \cdot A_s$).


								\begin{center}

								\begin{tikzpicture}

								\node [draw,

								    minimum width=2cm,

								    minimum height=1.2cm,

								    right=1cm

								    ]  (simulator) {simulator};

								\draw[-stealth] ++(-1,0) -- (simulator.west)

								    node[midway,above]{$g, X$};

								\draw[-stealth] (simulator.east) -- ++(+2,0)

								    node[midway,above]{$A_s, c_s, z_s$};

								\end{tikzpicture}

								\end{center}


								Internally, the simulator computes

								$$z_s \xleftarrow{r} \mathbb{F},~c_s \xleftarrow{r} \mathbb{F},~A_s = g^{z_s} \cdot X^{c_s}$$


								\subsection{Flow}

								For two known \emph{public keys} $X_0, X_1 \in G$, Alice knows $w_b \in \mathbb{F}$, for $b \in \{0, 1\}$, such that $g^{w_b} = X_0$ or $g^{w_b} = X_1$. As we don't know if Alice controls $0$ or $1$, from now on, we will use $b$ and $1-b$.

								\\

								So, Alice knows $w_b \in \mathbb{F}$ such that $X_b = g^{w_b}$, and does not know $w_{1-b}$ for $X_{1-b}=g^{w_{1-b}}$.


								\begin{enumerate}

								    \item First of all, as in the \emph{Sigma protocol}, Alice generates a random \emph{commitment} $a_b \xleftarrow{r} \mathbb{F}$, and computes $A_b = g^{a_b}$.

								    \item Then, Alice will run the \emph{simulator} for $1-b$.

									\begin{list}{}

									    \item Sets a random $c_{1-b} \xleftarrow{r} \mathbb{F}$, and runs the simulator with inputs\\$(c_{1-b}, X_{1-b})$, and outputs $(A_{1-b}, c_{1-b}, z_{1-b})$.

									    \item Remember that internally the \emph{simulator} will set random\\

										$z_{1-b}, c_{1-b} \xleftarrow{r} \mathbb{F}$, and compute an $A_{1-b}$ such that\\

										$A_{1-b} = g^{z_{1-b}} \cdot X_{1-b}^{c_{1-b}}$.

									\end{list}

									\item Now, Alice sends $A_b, A_{1-b}$ to Bob

									\item And Bob sends back the \emph{challenge} $s \xleftarrow{r} \mathbb{F}$.

									\item Alice then splits the challenge $s$ into $c_b, c_{1-b}$, by $s = c_{1-b} \oplus c_b$. So Alice can compute $c_b = s \oplus c_{1-b}$.

									\item Then Alice computes $z_b = a_b \cdot w_b + c_b$. And sends to Bob $(c_b, c_{1-b}, z_b, z_{1-b})$.

									\item Bob can perform the verification by checking that:

									\begin{enumerate}[i.]

									    \item $s == c_b \oplus c_{1-b}$

									    \item $g_{z_{1-b}} == A_{1-b} \cdot X_{1-b}^{-c_{1-b}}$

									    \item $g_{z_b} == A_b \cdot X_b^{-c_b}$

									\end{enumerate}

								\end{enumerate}


								\begin{center}

								\begin{sequencediagram}

								    \newinst[1]{a}{Alice}

								    \newinst[3]{b}{Bob}

								    \mess[1]{a}{$A_b, A_{1-b}$}{b}

								    \mess[1]{b}{$s$}{a}

								    \mess[1]{a}{$c_b, c_{1-b}, z_b, z_{1-b}$}{b}

								\end{sequencediagram}

								\end{center}


								\section{Resources}

								\begin{enumerate}

								    \item \href{https://cs.au.dk/~ivan/Sigma.pdf}{https://cs.au.dk/~ivan/Sigma.pdf}

								    \item \emph{Cryptography Made Simple}, Nigel Smart. Section 21.3.

								\end{enumerate}


								\end{document}