Add pairings initial notes

1 year ago · 11e7cc5613
10 changed files with 158 additions and 21 deletions
--- a/abstract-algebra-charles-pinter-notes.pdf
+++ b/abstract-algebra-charles-pinter-notes.pdf
--- a/abstract-algebra-charles-pinter-notes.tex
+++ b/abstract-algebra-charles-pinter-notes.tex
@ -179,7 +179,7 @@ Every subgroup of a cyclic group is cyclic.
 \end{theorem}

 \begin{theorem}[Lagrange's theorem]
    Let $G$ be a finite group, and $H$ any subgroup of $G$. The order of $G$ is a multiple of the order of $H$.
    Let $G$ be a finite group, and $H$ any subgroup of $G$. The order of $G$ is a multiple of the order of $H$. $|H|$ divides $|G|$.
 \end{theorem}
    Lagrange's theorem can be easily seen by the facts that:
    \begin{enumerate}[i.]
@ -187,7 +187,6 @@ Every subgroup of a cyclic group is cyclic.
 	\item $|Ha| = |H|$ (each coset has the same order as H). 
    \end{enumerate}


 By consequence,
 \begin{theorem}
    If $G$ is a group with a prime number $p$ of elements, then $G$ is a cyclic group. Furthermore, any element $a \neq e$ in $G$ is a generator of $G$.
@ -371,6 +370,18 @@ From the last two theorems: every integer $m$ can be factored into primes, and t
    $$a^{p-1} \equiv 1 \pmod p, \forall a \not\equiv 0 \pmod p$$
    \\
    So, by taking $a^{p-2} \cdot a \equiv 1 \pmod p$, where $a^{p-2} \equiv a^{-1} \pmod p$ (the inverse modulo p), we see that $a^p \equiv a \pmod p, \forall a \in \mathbb{Z}$, so $a^p - a$ is a multiple of $p$.

    ~\\\emph{Relation to Lagrange's theorem:}\\
    Let $G = \mathbb{Z}_p$, and let $H$ be the multiplicative subgroup of $G$ generated by $a$ (ie. $H = \{ 1, a, a^2, \ldots \}$). The order of $H$ ($h = |H|$), is also the order of $a$ (ie. smallest $n>1$ s.t. $a^n=1~mod~p$).

    By Lagrange's theorem, $h~|~|G| = p - 1$, so $p-1 = h \cdot m$, thus
    $$
    a^{p-1} = (a^h)^m \equiv 1^m \equiv 1~mod~p
    $$

    ~\\\emph{Another perspective:}\\
    We have $a^p \equiv a \pmod{p}$, by dividing by $a$ on both sides, we obtain $a^{p-1} \equiv 1 \pmod{p}$.

 \end{theorem}

 \begin{theorem}[Euler's $\phi$ function]
--- a/blind-sign-over-ec.sage
+++ b/blind-sign-over-ec.sage
@ -52,19 +52,19 @@ def verify(G, Q, sig, m):


 # ethereum elliptic curve
 p = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F
 p = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F # base field
 a = 0
 b = 7
 F = GF(p)
 F = GF(p) # base field
 E = EllipticCurve(F, [a,b])
 GX = 0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798
 GY = 0x483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8
 g = E(GX,GY)
 n = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141
 q = g.order()
 q = g.order() # order of Fp
 assert is_prime(p)
 assert is_prime(q)
 Fq = GF(q)
 Fq = GF(q) # scalar field



--- a/fft.sage
+++ b/fft.sage
@ -105,21 +105,25 @@ print("nth roots of unity:", w)
 print("Vandermonde matrix:")
 print(ft)

 a = vector([3,4,5,9])
 print("a:", a)
 fa_eval = vector([3,4,5,9])
 print("fa_eval:", fa_eval)

 # interpolate f_a(x)
 fa_coef = ft_inv * a
 fa_coef = ft_inv * fa_eval
 print("fa_coef:", fa_coef)

 P.<x> = PolynomialRing(F)
 fa = P(list(fa_coef))
 print("f_a(x):", fa)

 # check that evaluating fa(x) at the roots of unity returns the expected values of a
 for i in range(len(a)):
    assert fa(w[i]) == a[i]
 # check that evaluating fa(x) at the roots of unity returns the expected values of fa_eval
 for i in range(len(fa_eval)):
    assert fa(w[i]) == fa_eval[i]

 # go from coefficient form to evaluation form
 fa_eval2 = ft * fa_coef
 print("fa_eval'", fa_eval)
 assert fa_eval2 == fa_eval


 # Fast polynomial multiplicaton using FFT
--- a/ipa.sage
+++ b/ipa.sage
@ -181,7 +181,7 @@ class IPA_halo:
        # a, b, G have length=1
        # l, r are random blinding factors
        # L, R are the "cross-terms" of the inner product
        return a[0], b[0], G[0], l, r, L, R
        return a[0], l, r, L, R

    def verify(self, P, a, v, x_powers, r, u, U, lj, rj, L, R):
        print("methid verify()")
@ -358,7 +358,7 @@ class TestUtils(unittest.TestCase):


 class TestIPA_bulletproofs(unittest.TestCase):
        def test_inner_product(self):
        def test_inner_product_argument(self):
            d = 8
            ipa = IPA_bulletproofs(Fq, E, g, d)

@ -374,9 +374,6 @@ class TestIPA_bulletproofs(unittest.TestCase):
            v = ipa.evaluate(a, b)
            print("v", v)

            # verifier
            #  r = int(ipa.F.random_element())

            # verifier generate random challenges {uᵢ} ∈ 𝕀 and U ∈ 𝔾
            U = ipa.E.random_element()
            k = int(math.log(d, 2))
@ -418,7 +415,7 @@ class TestIPA_halo(unittest.TestCase):
            vc_c = vc_a + vc_b
            assert vc_c == expected_vc_c

        def test_inner_product(self):
        def test_inner_product_argument(self):
            d = 8
            ipa = IPA_halo(Fq, E, g, d)

@ -428,7 +425,7 @@ class TestIPA_halo(unittest.TestCase):
            x = ipa.F(3)
            x_powers = powers_of(x, ipa.d) # = b
            
            # verifier
            # blinding factor
            r = int(ipa.F.random_element())

            # prover
@ -438,6 +435,8 @@ class TestIPA_halo(unittest.TestCase):
            print("v", v)

            # verifier generate random challenges {uᵢ} ∈ 𝕀 and U ∈ 𝔾
            # This might be obtained from the hash of the transcript
            # (Fiat-Shamir heuristic for non-interactive version)
            U = ipa.E.random_element()
            k = int(math.log(ipa.d, 2))
            u = [None] * k
@ -449,7 +448,7 @@ class TestIPA_halo(unittest.TestCase):
            P = P + int(v) * U

            # prover
            a_ipa, b_ipa, G_ipa, lj, rj, L, R = ipa.ipa(a, x_powers, u, U)
            a_ipa, lj, rj, L, R = ipa.ipa(a, x_powers, u, U)

            # verifier
            print("P", P)
--- a/notes_bls-sig.pdf
+++ b/notes_bls-sig.pdf
--- a/notes_bls-sig.tex
+++ b/notes_bls-sig.tex
@ -73,7 +73,7 @@ Unfold:
 $$\fbox{e(pk_{aggr}, H(m))}= e(pk_1 + pk_2 + \ldots + pk_n, H(m)) =$$
 $$=e([sk_1] \cdot g_1 + [sk_2] \cdot g_1 + \ldots + [sk_n] \cdot g_1, H(m))=$$
 $$=e([sk_1 + sk_2 + \ldots + sk_n] \cdot g_1, H(m))=$$
 $$=e(g_1, H(m))^{(sk_1 + sk_2 + \ldots + sk_n)}=$$
 $$=[sk_1 + sk_2 + \ldots + sk_n]~\cdot~e(g_1, H(m))=$$
 $$=e(g_1, [sk_1 + sk_2 + \ldots + sk_n] \cdot H(m))=$$
 $$=e(g_1, [sk_1] \cdot H(m) + [sk_2] \cdot H(m) + \ldots + [sk_n] \cdot H(m))=$$
 $$=e(g_1, \sigma_1 + \sigma_2 + \ldots + \sigma_n)= \fbox{e(g_1, \sigma_{aggr})}$$
--- a/pairings.pdf
+++ b/pairings.pdf
--- a/pairings.tex
+++ b/pairings.tex
@ -0,0 +1,123 @@
 \documentclass{article}
 \usepackage[utf8]{inputenc}
 \usepackage{amsfonts}
 \usepackage{amsthm}
 \usepackage{amsmath}
 \usepackage{amssymb}
 \usepackage{enumerate}
 \usepackage{hyperref}
 \hypersetup{
    colorlinks,
    citecolor=black,
    filecolor=black,
    linkcolor=black,
    urlcolor=blue
 }
 % \usepackage{xcolor}

 % prevent warnings of underfull \hbox:
 % \usepackage{etoolbox}
 % \apptocmd{\sloppy}{\hbadness 4000\relax}{}{}

 \theoremstyle{definition}
 \newtheorem{definition}{Def}[section]
 \newtheorem{theorem}[definition]{Thm}
 \newtheorem{innersolution}{}
 \newenvironment{solution}[1]
 {\renewcommand\theinnersolution{#1}\innersolution}
 {\endinnersolution}


 \title{Bilinear Pairings - study}
 \author{arnaucube}
 \date{August 2022}

 \begin{document}

 \maketitle

 \begin{abstract}
  Notes taken from \href{https://sites.google.com/site/matanprasma/artifact}{Matan Prsma} math seminars and also while reading about Bilinear Pairings. Usually while reading papers and books 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. I use these notes to revisit the concepts after some time of reading the topic.
 \end{abstract}

 \tableofcontents

 \section{Weil reciprocity}

 \section{Generic Weil Pairing}

 \begin{definition}{Divisor}
  $$D= \sum_{P \in E(\mathbb{K})} n_p \cdot [P]$$
 \end{definition}

 \begin{definition}{Degree \& Sum}
  $$deg(D)= \sum_{P \in E(\mathbb{K})} n_p$$
  $$sum(D)= \sum_{P \in E(\mathbb{K})} n_p \cdot P$$
 \end{definition}

 \begin{definition}{Principal divisor}
  iff $deg(D)=0$ and $sum(D)=0$
 \end{definition}
 $D \sim D'$ iff $D - D'$ is principal.


 \begin{definition}{Evaluation of a rational function}
  $$r(D)= \prod r(P)^{n_p}$$
 \end{definition}

 \subsection{Generic Weil Pairing}
 Let $E(\mathbb{K})$, with $\mathbb{K}$ of char $p$, $n$ s.t. $p \nmid n$.

 $\mathbb{K}$ large enough: $E(\mathbb{K})[n] = E(\mathbb{\overline{K}}) = \mathbb{Z}_n \oplus \mathbb{Z}_n$ (with $n^2$ elements).

 $P, Q \in E[n]$:
 $$D_P \sim [P] - [0]$$
 $$D_Q \sim [Q] - [0]$$
 We need them to have disjoint support:
 $$D_P \sim [P] - [0]$$
 $$D_Q \sim [Q+T] - [T]$$

 $$\Delta D = D_Q - D_Q' = [Q] - [0] - [Q+T] + [T]$$


 \section{Exercises}
 \emph{An Introduction to Mathematical Cryptography, 2nd Edition} - Section 6.8. Bilinear pairings on elliptic curves

 \begin{solution}{6.29}
  $div(R(x) \cdot S(x)) = div( R(x)) + div( S(x))$, where $R(x), S(x)$ are rational functions.
  \\proof:\\
  \emph{Norm} of $f$: $N_f = f \cdot \overline{f}$, and we know that $N_{fg} = N_f \cdot N_g~\forall~\mathbb{K}[E]$,\\
  then $$deg(f) = deg_x(N_f)$$\\
  and $$deg(f \cdot g) = deg(f) + deg(g)$$

  Proof:
  $$deg(f \cdot g) = deg_x(N_{fg}) = deg_x(N_f \cdot N_g)$$
  $$= deg_x(N_f) + deg_x(N_g) = deg(f) + deg(g)$$

  So, $\forall P \in E(\mathbb{K}),~ ord_P(rs) = ord_P(r) + ord_P(s)$.\\
  As $div(r) = \sum_{P\in E(\mathbb{K})} ord_P(r)[P]$, $div(s) = \sum ord_P(s)[P]$.

  So,
  $$div(rs) = \sum ord_P(rs)[P]$$
  $$= \sum ord_P(r)[P] + \sum ord_P(s)[P] = div(r) + div(s)$$
 \end{solution}

 \vspace{0.5cm}

 \begin{solution}{6.31}
  $$e_m(P, Q) = e_m(Q, P)^{-1} \forall P, Q \in E[m]$$
  Proof:
  We know that $e_m(P, P) = 1$, so:
  $$1 = e_m(P+Q, P+Q) = e_m(P, P) \cdot e_m(P, Q) \cdot e_m(Q, P) \cdot e_m(Q, Q)$$

  and we know that $e_m(P, P) = 1$, then we have:
  $$1 = e_m(P, Q) \cdot e_m(Q, P)$$
  $$\Longrightarrow e_m(P, Q) = e_m(Q, P)^{-1}$$
 \end{solution}




 \end{document}
--- a/sigma-or-notes.pdf
+++ b/sigma-or-notes.pdf