\documentclass{article} \usepackage[utf8]{inputenc} \usepackage{amsfonts} \usepackage{amsthm} \usepackage{amsmath} \usepackage{mathtools} \usepackage{enumerate} \usepackage{hyperref} \usepackage{xcolor} \usepackage{pgf-umlsd} % diagrams \usepackage{centernot} % prevent warnings of underfull \hbox: \usepackage{etoolbox} \apptocmd{\sloppy}{\hbadness 4000\relax}{}{} \theoremstyle{definition} \newtheorem{definition}{Def}[section] \newtheorem{theorem}[definition]{Thm} % custom lemma environment to set custom numbers \newtheorem{innerlemma}{Lemma} \newenvironment{lemma}[1] {\renewcommand\theinnerlemma{#1}\innerlemma} {\endinnerlemma} \title{Notes on Spartan} \author{arnaucube} \date{April 2023} \begin{document} \maketitle \begin{abstract} Notes taken while reading about Spartan \cite{cryptoeprint:2019/550}. Usually while reading papers I take handwritten notes, this document contains some of them re-written to $LaTeX$. The notes are not complete, don't include all the steps neither all the proofs. \end{abstract} \tableofcontents \section{R1CS into Sum-Check protocol} \begin{definition}{R1CS} $\exists w \in \mathbb{F}^{m - |io| - 1}$ such that $(A \cdot z) \circ (B \cdot z) = (C \cdot z)$, where $z=(io, 1, w)$. \end{definition} \textbf{Thm 4.1} $\forall$ R1CS instance $x = (\mathbb{F}, A, B, C, io, m, n)$, $\exists$ a degree-3 log m-variate polynomial $G$ such that $\sum_{x \in \{0,1\}^{log m}} G(x) = 0$ iff $\exists$ a witness $w$ such that $Sat_{R1CS}(x, w)=1$. % \begin{theorem}{4.1} // TODO use theorem gadget % $\forall$ % \begin{end} \vspace{0.5cm} % For a RCS instance $x$, let $s = \lceil \log m \rceil$. We can view matrices $A, B, C \in \mathbb{F}^{m \times m}$ as functions $\{0,1\}^s \times \{0,1\}^s \rightarrow \mathbb{F}$ ($s= \lceil \log m \rceil$). For a given witness $w$ to $x$, let $z=(io, 1, w)$. View $z$ as a function $\{0,1\}^s \rightarrow \mathbb{F}$, so any entry in $z$ can be accessed with a $s$-bit identifier. \begin{small} $$ F_{io}(x)=\left( \sum_{y \in \{0,1\}^s} A(x, y) \cdot Z(y) \right) \cdot \left( \sum_{y \in \{0,1\}^s} B(x, y) \cdot Z(y) \right) - \sum_{y \in \{0,1\}^s} C(x, y) \cdot Z(y) $$ \end{small} \begin{lemma}{4.1} $\forall x \in \{0,1\}^s,~ F_{io}(x)=0$ iff $Sat_{R1CS}(x,w)=1$. \end{lemma} $F_{io}(\cdot)$ is a function, not a polynomial, so it can not be used in the Sum-check protocol. $F_{io}(x)$ function is converted to a polynomial by using its polynomial extension $\widetilde{F}_{io}(x): \mathbb{F}^s \rightarrow \mathbb{F}$, \begin{small} $$ \widetilde{F}_{io}(x)=\left( \sum_{y \in \{0,1\}^s} \widetilde{A}(x, y) \cdot \widetilde{Z}(y) \right) \cdot \left( \sum_{y \in \{0,1\}^s} \widetilde{B}(x, y) \cdot \widetilde{Z}(y) \right) - \sum_{y \in \{0,1\}^s} \widetilde{C}(x, y) \cdot \widetilde{Z}(y) $$ \end{small} \begin{lemma}{4.2} $\forall x \in \{0,1\}^s,~ \widetilde{F}_{io}(x)=0$ iff $Sat_{R1CS}(x, w)=1$. \end{lemma} (proof: $\forall x \in \{0,1\}^s,~ \widetilde{F}_{io}(x)=F_{io}(x)$, so, result follows from Lemma 4.1.) % TODO link to lemma \vspace{0.5cm} So, for this, V will need to check that $\widetilde{F}_{io}$ vanishes over the boolean hypercube ($\widetilde{F}_{io}(x)=0 ~\forall x \in \{0,1\}^s$). Recall that $\widetilde{F}_{io}(\cdot)$ is a low-degree multivariate polynomial over $\mathbb{F}$ in $s$ variables. Thus, checking that $\widetilde{F}_{io}$ vanishes over the boolean hypercube is equivalent to checking that $\widetilde{F}_io=0$. Thus, V can check $\sum_{x \in \{0,1\}^s} \widetilde{F}_{io}(x)=0$ using the Sum-check protocol (through SZ lemma, V can check if for a random value it equals to 0, and be convinced that applies to all the points whp.). But: as $\widetilde{F}_{io}(x)$ is not multilinear, so $\sum_{x\in \{0,1\}^s} \widetilde{F}_{io}(x)=0 \centernot\Longleftrightarrow F_{io}(x)=0 ~\forall x \in \{0,1\}^s$. Bcs: the $2^s$ terms in the sum might cancel each other even when the individual terms are not zero. Solution: combine $\widetilde{F}_{io}(x)$ with $\widetilde{eq}(t, x)$ to get $Q_{io}(t, x)$ which will be the unique multilinear polynomial, and then check that it is a zero-polynomial $$Q_{io}(t)= \sum_{x \in \{0,1\}^s} \widetilde{F}_{io}(x) \cdot \widetilde{eq}(t, x)$$ where $\widetilde{eq}(t, x) = \prod_{i=1}^s (t_i \cdot x_i + (1- t_i) \cdot (1- x_i))$, which is the MLE of $eq(x,e)= \{ 1 ~\text{if}~ x=e,~ 0 ~\text{otherwise} \}$. Basically $Q_{io}(\cdot)$ is a multivariate (the unique multilinear) polynomial such that $$Q_{io}(t) = \widetilde{F}_{io}(t) ~\forall t \in \{0,1\}^s$$ thus, $Q_{io}(\cdot)$ is a zero-polynomial iff $\widetilde{F}_{io}(x)=0 ~\forall x\in \{0,1\}^s$. $\Longleftrightarrow$ iff $\widetilde{F}_{io}(\cdot)$ encodes a witness $w$ such that $Sat_{R1CS}(x, w)=1$. $\widetilde{F}_{io}(x)$ has degree 2 in each variable, and $\widetilde{eq}(t, x)$ has degree 1 in each variable, so $Q_{io}(t)$ has degree 3 in each variable. To check that $Q_{io}(\cdot)$ is a zero-polynomial: check $Q_{io}(\tau)=0,~ \tau \in^R \mathbb{F}^s$ (Schwartz-Zippel-DeMillo–Lipton lemma) through the sum-check protocol. This would mean that the R1CS instance is satisfied. \paragraph{Recap} \begin{itemize} \item[] We have that $Sat_{R1CS}(x,w)=1$ iff $F_{io}(x)=0$. \item[] To be able to use sum-check, we use its polynomial extension $\widetilde{F}_{io}(x)$, using sum-check to prove that $\widetilde{F}_{io}(x) =0 ~\forall x \in \{0, 1\}^s$, which means that $Sat_{R1CS}(x,~w)=1$. \item[] To prevent potential canceling terms, we combine $\widetilde{F}_{io}(x)$ with $\widetilde{eq}(t, x)$, obtaining $G_{io, \tau}(x)= \widetilde{F}_{io}(x) \cdot \widetilde{eq}(t, x)$. \item[] Thus $Q_{io}(t)= \sum_{x \in \{0,1\}^s} \widetilde{F}_{io}(x) \cdot \widetilde{eq}(t, x)$, and then we prove that $Q_{io}(\tau)=0$, for $\tau \in^R \mathbb{F}^s$. \end{itemize} \section{NIZKs with succint proofs for R1CS} From Thm 4.1: to check R1CS instance $(\mathbb{F}, A, B, C, io, m, n)$ V can check if $\sum_{x \in \{0,1\}^s} G_{io, \tau} (x) = 0$, which through sum-check protocol can be reduced to $e_x = G_{io, \tau} (r_x)$, where $r_x \in \mathbb{F}^s$. Recall: $G_{io, \tau}(x) = \widetilde{F}_{io}(x) \cdot \widetilde{eq}(\tau, x)$. Evaluating $\widetilde{eq}(\tau, r_x)$ takes $O(log~m)$, but to evaluate $\widetilde{F}_{io}(r_x)$, V needs to evaluate $$\widetilde{A}(r_x, y), \widetilde{B}(r_x, y), \widetilde{C}(r_x, y), \widetilde{Z}(y),~ \forall y \in \{0,1\}^s$$ which requires 3 sum-check instances (\begin{scriptsize} $\left( \sum_{y \in \{0,1\}^s} \widetilde{A}(x, y) \cdot \widetilde{Z}(y) \right)$,\\ $\left( \sum_{y \in \{0,1\}^s} \widetilde{B}(x, y) \cdot \widetilde{Z}(y) \right)$, $\left( \sum_{y \in \{0,1\}^s} \widetilde{C}(x, y) \cdot \widetilde{Z}(y) \right)$ \end{scriptsize}), one for each summation in\\ $\widetilde{F}_{io}(x)$. But note that evaluations of $\widetilde{Z}(y) ~\forall y \in \{0,1\}^s$ are already known as $(io, 1, w)$. Solution: combination of 3 protocols: \begin{itemize} \item Sum-check protocol \item randomized mini protocol \item polynomial commitment scheme \end{itemize} Basically to do a random linear combination of the 3 summations to end up doing just a single sum-check. Observation: let $\widetilde{F}_{io}(r_x) = \overline{A}(r_x) \cdot \overline{B}(r_x) - \overline{C}(r_x)$, where $$\overline{A}(r_x) = \sum_{y \in \{0,1\}} \widetilde{A}(r_x, y) \cdot \widetilde{Z}(y),~~\overline{B}(r_x) = \sum_{y \in \{0,1\}} \widetilde{B}(r_x, y) \cdot \widetilde{Z}(y)$$ $$\overline{C}(r_x) = \sum_{y \in \{0,1\}} \widetilde{C}(r_x, y) \cdot \widetilde{Z}(y)$$ Prover makes 3 separate claims: $\overline{A}(r_x)=v_A,~ \overline{B}(r_x)=v_B,~ \overline{C}(r_x)=v_C$, then V evaluates: $$G_{io, \tau}(r_x) = (v_A \cdot v_B - v_C) \cdot \widetilde{eq}(r_x, \tau)$$ \begin{footnotesize} which equals to $$=\left(\overline{A}(r_x) \cdot \overline{B}(r_x) - \overline{C}(r_x)\right) \cdot \widetilde{eq}(r_x, \tau)=$$ $$\left(\left(\sum_{y \in \{0,1\}} \widetilde{A}(r_x, y) \cdot \widetilde{Z}(y)\right) \cdot \left(\sum_{y \in \{0,1\}} \widetilde{B}(r_x, y) \cdot \widetilde{Z}(y)\right) - \sum_{y \in \{0,1\}} \widetilde{C}(r_x, y) \cdot \widetilde{Z}(y)\right) \cdot \widetilde{eq}(r_x, \tau)$$ \end{footnotesize} \vspace{0.5cm} This would be 3 sum-check protocol instances (3 claims: $\overline{A}(r_x)=v_A$, $\overline{B}(r_x)=v_B$, $\overline{C}(r_x)=v_C$). Instead, combine 3 claims into a single claim: \begin{itemize} \item V samples $r_A, r_B, r_C \in^R \mathbb{F}$, and computes $c= r_A v_A + r_B v_B + r_C v_C$. \item V, P use sum-check protocol to check: $$r_A \cdot \overline{A}(r_x) + r_B \cdot \overline{B}(r_x) + r_C \cdot \overline{C}(r_x) == c$$ % Let $L(r_x) = r_A \cdot \overline{A}(r_x) +r_B \cdot \overline{B}(r_x) +r_C \cdot \overline{C}(r_x)$, Let \begin{small} \begin{align*} &L(r_x) = r_A \cdot \overline{A}(r_x) +r_B \cdot \overline{B}(r_x) +r_C \cdot \overline{C}(r_x)\\ &= \sum_{y \in \{0,1\}^s} \left( r_A \cdot \widetilde{A}(r_x, y) \cdot \widetilde{Z}(y) + r_B \cdot \widetilde{B}(r_x, y) \cdot \widetilde{Z}(y) + r_C \cdot \widetilde{C}(r_x, y) \cdot \widetilde{Z}(y) \right)\\ &= \sum_{y \in \{0,1\}^s} M_{r_x}(y) \end{align*} \end{small} $M_{r_x}(y)$ is a s-variate polynomial with deg $\leq 2$ in each variable ($\Longleftrightarrow \mu = s,~ l=2,~ T=c$). \end{itemize} \begin{align*} M_{r_x}(r_y) &= r_A \cdot \widetilde{A}(r_x, r_y) \cdot \widetilde{Z}(r_y) + r_B \cdot \widetilde{B}(r_x, r_y) \cdot \widetilde{Z}(r_y) + r_C \cdot \widetilde{C}(r_x, r_y) \cdot \widetilde{Z}(r_y)\\ &= (r_A \cdot \widetilde{A}(r_x, r_y) + r_B \cdot \widetilde{B}(r_x, r_y) + r_C \cdot \widetilde{C}(r_x, r_y)) \cdot \widetilde{Z}(r_y)\\ \end{align*} only one term in $M_{r_x}(r_y)$ depends on prover's witness: $\widetilde{Z}(r_y)$, the other terms can be computed locally by V in $O(n)$ time (Section 6 of the paper for sub-linear in $n$). Instead of evaluating $\widetilde{Z}(r_y)$ in $O(|w|)$ communications, P sends a commitment to $\widetilde{w}(\cdot)$ (= MLE of the witness $w$) to V before the first instance of the sum-check protocol. \paragraph{Recap} \begin{itemize} \item[] To check the R1CS instance, V can check $\sum_{x \in \{0,1\}^s} G_{io, \tau} (x) = 0$, which through the sum-check is reduced to $e_x = G_{io, \tau} (r_x)$, for $r_x \in \mathbb{F}^s$. \item[] Evaluating $G_{io, \tau}(x)$ ($G_{io, \tau}(x) = \widetilde{F}_{io}(x) \cdot \widetilde{eq}(\tau, x)$) is not cheap. Evaluating $\widetilde{eq}(\tau, r_x)$ takes $O(log~m)$, but to evaluate $\widetilde{F}_{io}(r_x)$, V needs to evaluate $\widetilde{A}, \widetilde{B}, \widetilde{C}, \widetilde{Z},~ \forall y \in \{0,1\}^s$ % \item[] Solution: combine 3 protocols: sum-check protocol, randomized mini protocol, polynomial commitment scheme. \item[] P makes 3 separate claims: $\overline{A}(r_x)=v_A,~ \overline{B}(r_x)=v_B,~ \overline{C}(r_x)=v_C$, so V can evaluate $G_{io, \tau}(r_x) = (v_A \cdot v_B - v_C) \cdot \widetilde{eq}(r_x, \tau)$ \item[] The previous claims are combined into a single claim (random linear combination) to use only a single sum-check protocol: \begin{itemize} \item[] P: $c= r_A v_A + r_B v_B + r_C v_C$, for $r_A, r_B, r_C \in^R \mathbb{F}$ \item[] V, P: sum-check $r_A \cdot \overline{A}(r_x) + r_B \cdot \overline{B}(r_x) + r_C \cdot \overline{C}(r_x) == c$ \end{itemize} \item[] $c=L(r_x)=\sum_{y \in \{0,1\}^s} M_{r_x}(y)$, where $M_{r_x}(y)$ is a s-variate polynomial with deg $\leq 2$ in each variable ($\Longleftrightarrow \mu = s,~ l=2,~ T=c$). Only $\widetilde{Z}(r_y)$ depends on P's witness, the other terms can be computed locally by V. \item[] Instead of evaluating $\widetilde{Z}(r_y)$ in $O(|w|)$ communications, P uses a commitment to $\widetilde{w}(\cdot)$ (= MLE of the witness $w$). \end{itemize} \subsection{Full protocol} \begin{footnotesize} (Recall: Sum-Check params: $\mu$: n vars, n rounds, $l$: degree in each variable upper bound, $T$: claimed result.) \end{footnotesize} \begin{itemize} \item $pp \leftarrow Setup(1^{\lambda})$: invoke $pp \leftarrow PC.Setup(1^{\lambda}, log m)$; output $pp$ \item $b \leftarrow
(\mathbb{F}, A,B,C, io, m, n)$:
\begin{enumerate}
\item P: $(C, S) \leftarrow PC.Commit(pp, \widetilde{w})$ and send $C$ to V
\item V: send $\tau \in^R \mathbb{F}^{log~m}$ to P
\item let $T_1=0,~ \mu_1=log~m,~ l_1=3$
\item V: set $r_x \in^R \mathbb{F}^{\mu_1}$
\item Sum-check 1. $e_x \leftarrow