mirror of https://github.com/zcash/halo2.git
[book] Add macros, constraint tables, and region layout to Commit^ivk
I also merged in content from a page I wrote independently while reviewing the Action circuit PR, and made various cleanups to the Markdown source.
This commit is contained in:
parent
4a5a4cc437
commit
f376a61bb8
|
@ -6,3 +6,4 @@ src = "src"
|
||||||
title = "The Orchard Book"
|
title = "The Orchard Book"
|
||||||
|
|
||||||
[preprocessor.katex]
|
[preprocessor.katex]
|
||||||
|
macros = "macros.txt"
|
||||||
|
|
|
@ -0,0 +1,28 @@
|
||||||
|
# Conventions
|
||||||
|
|
||||||
|
\bconcat:{\mathop{\kern 0.1em||\kern 0.1em}}
|
||||||
|
|
||||||
|
# Conversions
|
||||||
|
|
||||||
|
\ItoLEBSP:{\mathsf{I2LEBSP}_{#1}}
|
||||||
|
|
||||||
|
# Fields and curves
|
||||||
|
|
||||||
|
\BaseLength:{\ell^\mathsf{#1\vphantom{p}}_{\mathsf{base}}}
|
||||||
|
|
||||||
|
# Key components
|
||||||
|
|
||||||
|
\AuthSignPublic:{\mathsf{ak}}
|
||||||
|
\NullifierKey:{\mathsf{nk}}
|
||||||
|
\InViewingKey:{\mathsf{ivk}}
|
||||||
|
|
||||||
|
# Commitments and hashes
|
||||||
|
|
||||||
|
\SinsemillaHash:{\mathsf{SinsemillaHash}}
|
||||||
|
\SinsemillaShortCommit:{\mathsf{SinsemillaShortCommit}}
|
||||||
|
\CommitIvk:{\mathsf{Commit}^{\InViewingKey}}
|
||||||
|
|
||||||
|
# Circuit constraint helper methods
|
||||||
|
|
||||||
|
\BoolCheck:{\texttt{bool\_check}({#1})}
|
||||||
|
\ShortLookupRangeCheck:{\texttt{short\_lookup\_range\_check}({#1})}
|
|
@ -1,76 +1,229 @@
|
||||||
# CommitIvk
|
# CommitIvk
|
||||||
|
|
||||||
## Message decomposition
|
## Message decomposition
|
||||||
$\mathsf{SinsemillaShortCommit}$ is used in the [$\mathsf{CommitIvk}$ function](https://zips.z.cash/protocol/protocol.pdf#concretesinsemillacommit). The input to $\mathsf{SinsemillaShortCommit}$ is:
|
|
||||||
|
|
||||||
$$\mathsf{I2LEBSP}_{\ell_{\textsf{base}}^{\textsf{Orchard}}}(ak) || \mathsf{I2LEBSP}_{\ell_{\textsf{base}}^{\textsf{Orchard}}}(nk),$$
|
$\SinsemillaShortCommit$ is used in the
|
||||||
|
[$\CommitIvk$ function](https://zips.z.cash/protocol/protocol.pdf#concretesinsemillacommit).
|
||||||
|
The input to $\SinsemillaShortCommit$ is:
|
||||||
|
|
||||||
where $\mathsf{ak, nk}$ are Pallas base field elements, and $\ell_{\textsf{base}}^{\textsf{Orchard}} = 255.$
|
$$\ItoLEBSP{\BaseLength{Orchard}}(\AuthSignPublic) \bconcat \ItoLEBSP{\BaseLength{Orchard}}(\NullifierKey),$$
|
||||||
|
|
||||||
We break these inputs into the following `MessagePiece`s:
|
where $\AuthSignPublic$, $\NullifierKey$ are Pallas base field elements, and $\BaseLength{Orchard} = 255.$
|
||||||
|
|
||||||
|
Sinsemilla operates on multiples of 10 bits, so we start by decomposing the message into
|
||||||
|
chunks:
|
||||||
|
|
||||||
$$
|
$$
|
||||||
\begin{aligned}
|
\begin{align}
|
||||||
a \text{ (250 bits)} &= \text{bits } 0..=249 \text{ of } \mathsf{ak} \\
|
\ItoLEBSP{\BaseLength{Orchard}}(\AuthSignPublic) &= a \bconcat b_0 \bconcat b_1 \\
|
||||||
b \text{ (10 bits)} &= b_0||b_1||b_2 \\
|
&= (\text{bits 0..=249 of } \AuthSignPublic) \bconcat
|
||||||
&= (\text{bits } 250..=253 \text{ of } \mathsf{ak}) || (\text{bit } 254 \text{ of } \mathsf{ak}) || (\text{bits } 0..=4 \text{ of } \mathsf{nk}) \\
|
(\text{bits 250..=253 of } \AuthSignPublic) \bconcat
|
||||||
c \text{ (240 bits)} &= \text{bits } 5..=244 \text{ of } \mathsf{nk} \\
|
(\text{bit 254 of } \AuthSignPublic) \\
|
||||||
d \text{ (10 bits)} &= d_0||d_1 \\
|
\ItoLEBSP{\BaseLength{Orchard}}(\NullifierKey) &= b_2 \bconcat c \bconcat d_0 \bconcat d_1 \\
|
||||||
&= (\text{bits } 245..=253 \text{ of } \mathsf{nk}) || (\text{bit } 254 \text{ of } \mathsf{nk})
|
&= (\text{bits 0..=4 of } \NullifierKey) \bconcat
|
||||||
\end{aligned}
|
(\text{bits 5..=244 of } \NullifierKey) \bconcat
|
||||||
|
(\text{bits 245..=253 of } \NullifierKey) \bconcat
|
||||||
|
(\text{bit 254 of } \NullifierKey) \\
|
||||||
|
\end{align}
|
||||||
$$
|
$$
|
||||||
|
|
||||||
$a,b,c,d$ are constrained by the $\textsf{SinsemillaHash}$ to be $250$ bits, $10$ bits, $240$ bits, and $10$ bits respectively.
|
Then we recompose the chunks into message pieces:
|
||||||
|
|
||||||
In a custom gate, we check this message decomposition by enforcing the following constraints:
|
$$
|
||||||
|
\begin{array}{|c|l|}
|
||||||
|
\hline
|
||||||
|
\text{Length (bits)} & \text{Piece} \\\hline
|
||||||
|
250 & a \\
|
||||||
|
10 & b = b_0 \bconcat b_1 \bconcat b_2 \\
|
||||||
|
240 & c \\
|
||||||
|
10 & d = d_0 \bconcat d_1 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
||||||
1. $b = b_0 + 2^4 \cdot b_1 + 2^5 \cdot b_2$
|
Each message piece is constrained by $\SinsemillaHash$ to its stated length. Additionally,
|
||||||
<br>
|
$\AuthSignPublic$ and $\NullifierKey$ are witnessed as field elements, so we know they are
|
||||||
$b_0, b_2$ are witnessed outside this gate, and constrained to be $4$ bits and $5$ bits respectively. $b_1$ is witnessed and boolean-constrained in this gate:
|
canonical. However, we need additional constraints to enforce that:
|
||||||
$$(b_1)(1 - b_1) = 0.$$
|
|
||||||
From these witnessed subpieces, we check that we recover the original `MessagePiece` input to the hash:
|
|
||||||
$$b = b_0 + 2^4 \cdot b_1 + 2^5 \cdot b_2.$$
|
|
||||||
|
|
||||||
2. $d = d_0 + 2^9 \cdot d_1$
|
- The chunks are the correct bit lengths (or else they could overlap in the decompositions
|
||||||
<br>
|
and allow the prover to witness an arbitrary $\SinsemillaShortCommit$ message).
|
||||||
$d_0$ is witnessed outside this gate, and constrained to be $9$ bits. $d_1$ is witnessed and boolean-constrained in this gate:
|
- The chunks contain the canonical decompositions of $\AuthSignPublic$ and $\NullifierKey$
|
||||||
$$(d_1)(1 - d_1) = 0.$$
|
(or else the prover could witness an input to $\SinsemillaShortCommit$ that is
|
||||||
From these witnessed subpieces, we check that we recover the original `MessagePiece` input to the hash:
|
equivalent to $\AuthSignPublic$ and $\NullifierKey$ but not identical).
|
||||||
$$d = d_0 + 2^9 \cdot d_1.$$
|
|
||||||
|
Some of these constraints can be implemented with reusable circuit gadgets. We define a
|
||||||
|
custom gate controlled by the selector $q_\CommitIvk$ to hold the remaining constraints.
|
||||||
|
|
||||||
|
## Bit length constraints
|
||||||
|
|
||||||
|
Chunks $a$ and $c$ are directly constrained by Sinsemilla. For the remaining chunks, we
|
||||||
|
use the following constraints:
|
||||||
|
|
||||||
|
$$
|
||||||
|
\begin{array}{|c|l|}
|
||||||
|
\hline
|
||||||
|
\text{Degree} & \text{Constraint} \\\hline
|
||||||
|
& \ShortLookupRangeCheck{b_0, 4} \\\hline
|
||||||
|
& \ShortLookupRangeCheck{b_2, 5} \\\hline
|
||||||
|
& \ShortLookupRangeCheck{d_0, 9} \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot \BoolCheck{b_1} = 0 \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot \BoolCheck{d_1} = 0 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
||||||
|
where $\BoolCheck{x} = x \cdot (1 - x)$ and $\ShortLookupRangeCheck{}$ is a
|
||||||
|
[short lookup range check](../lookup_range_check.md#short-range-check).
|
||||||
|
|
||||||
|
## Decomposition constraints
|
||||||
|
|
||||||
We have now derived or witnessed every subpiece, and range-constrained every subpiece:
|
We have now derived or witnessed every subpiece, and range-constrained every subpiece:
|
||||||
|
- $a$ ($250$ bits) is witnessed and constrained outside the gate;
|
||||||
- $b_0$ ($4$ bits) is witnessed and constrained outside the gate;
|
- $b_0$ ($4$ bits) is witnessed and constrained outside the gate;
|
||||||
- $b_1$ ($1$ bits) is witnessed and boolean-constrained in the gate;
|
- $b_1$ ($1$ bits) is witnessed and boolean-constrained in the gate;
|
||||||
- $b_2$ ($5$ bits) is witnessed and constrained outside the gate;
|
- $b_2$ ($5$ bits) is witnessed and constrained outside the gate;
|
||||||
|
- $c$ ($240$ bits) is witnessed and constrained outside the gate;
|
||||||
- $d_0$ ($9$ bits) is witnessed and constrained outside the gate;
|
- $d_0$ ($9$ bits) is witnessed and constrained outside the gate;
|
||||||
- $d_1$ ($1$ bits) is witnessed and boolean-constrained in the gate,
|
- $d_1$ ($1$ bits) is witnessed and boolean-constrained in the gate.
|
||||||
and we use them to reconstruct the original field element inputs:
|
|
||||||
|
|
||||||
3. $\textsf{ak} = a + 2^{250} \cdot b_0 + 2^{254} \cdot b_1$
|
We can now use them to reconstruct both the (chunked) message pieces, and the original
|
||||||
4. $\textsf{nk} = b_2 + 2^5 \cdot c + 2^{245} \cdot d_0 + 2^{254} \cdot d_1$
|
field element inputs:
|
||||||
|
|
||||||
## Canonicity
|
$$
|
||||||
The modulus of the Pallas base field is $p = 2^{254} + t_p,$ where $t_p = 45560315531419706090280762371685220353 < 2^{126}.$
|
\begin{align}
|
||||||
|
b &= b_0 + 2^4 \cdot b_1 + 2^5 \cdot b_2 \\
|
||||||
|
d &= d_0 + 2^9 \cdot d_1 \\
|
||||||
|
\AuthSignPublic &= a + 2^{250} \cdot b_0 + 2^{254} \cdot b_1 \\
|
||||||
|
\NullifierKey &= b_2 + 2^5 \cdot c + 2^{245} \cdot d_0 + 2^{254} \cdot d_1 \\
|
||||||
|
\end{align}
|
||||||
|
$$
|
||||||
|
|
||||||
### $\textsf{ak} = a (250 \text{ bits}) || b_0 (4 \text{ bits}) || b_1 (1 \text{ bit})$
|
$$
|
||||||
We check that $\mathsf{I2LEBSP_{\ell_{base}^{Orchard}}(ak)}$ is a canonically-encoded $255$-bit value, i.e. $\textsf{ak} < p$. If the high bit is not set $b_1 = 0$, we are guaranteed that $\textsf{ak} < 2^{254}$. Thus, we are only interested in cases when $b_1 = 1 \implies \textsf{ak} \geq 2^{254}$. In these cases, we check that $\textsf{ak}_{0..=253} < t_p < 2^{126}$:
|
\begin{array}{|c|l|}
|
||||||
|
\hline
|
||||||
|
\text{Degree} & \text{Constraint} \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (b - (b_0 + b_1 \cdot 2^4 + b_2 \cdot 2^5)) = 0 \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (d - (d_0 + d_1 \cdot 2^9)) = 0 \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (a + b_0 \cdot 2^{250} + b_1 \cdot 2^{254} - \AuthSignPublic) = 0 \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (b_2 + c \cdot 2^5 + d_0 \cdot 2^{245} + d_1 \cdot 2^{254} - \NullifierKey) = 0 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
||||||
|
## Canonicity checks
|
||||||
|
|
||||||
|
At this point, we have constrained $\ItoLEBSP{\BaseLength{Orchard}}(\AuthSignPublic)$ and
|
||||||
|
$\ItoLEBSP{\BaseLength{Orchard}}(\NullifierKey)$ to be 255-bit values, with top bits $b_1$
|
||||||
|
and $d_1$ respectively. We have also constrained:
|
||||||
|
|
||||||
|
$$
|
||||||
|
\begin{align}
|
||||||
|
\ItoLEBSP{\BaseLength{Orchard}}(\AuthSignPublic) &= \AuthSignPublic \pmod{q_\mathbb{P}} \\
|
||||||
|
\ItoLEBSP{\BaseLength{Orchard}}(\NullifierKey) &= \NullifierKey \pmod{q_\mathbb{P}} \\
|
||||||
|
\end{align}
|
||||||
|
$$
|
||||||
|
|
||||||
|
where $q_\mathbb{P}$ is the Pallas base field modulus. The remaining constraints will
|
||||||
|
enforce that these are indeed canonically-encoded field elements, i.e.
|
||||||
|
|
||||||
|
$$
|
||||||
|
\begin{align}
|
||||||
|
\ItoLEBSP{\BaseLength{Orchard}}(\AuthSignPublic) &< q_\mathbb{P} \\
|
||||||
|
\ItoLEBSP{\BaseLength{Orchard}}(\NullifierKey) &< q_\mathbb{P} \\
|
||||||
|
\end{align}
|
||||||
|
$$
|
||||||
|
|
||||||
|
The Pallas base field modulus has the form $q_\mathbb{P} = 2^{254} + t_\mathbb{P}$, where
|
||||||
|
$$t_\mathbb{P} = \mathtt{0x224698fc094cf91b992d30ed00000001}$$
|
||||||
|
is 126 bits. We therefore know that if the top bit is not set, then the remaining bits
|
||||||
|
will always comprise a canonical encoding of a field element. Thus the canonicity checks
|
||||||
|
below are enforced if and only if $b_1 = 1$ (for $\AuthSignPublic$) or $d_1 = 1$ (for
|
||||||
|
$\NullifierKey$).
|
||||||
|
|
||||||
|
> In the constraints below we use a base-$2^{10}$ variant of the method used in libsnark
|
||||||
|
> (originally from [[SVPBABW2012](https://eprint.iacr.org/2012/598.pdf), Appendix C.1]) for
|
||||||
|
> range constraints $0 \leq x < t$:
|
||||||
|
>
|
||||||
|
> - Let $t'$ be the smallest power of $2^{10}$ greater than $t$.
|
||||||
|
> - Enforce $0 \leq x < t'$.
|
||||||
|
> - Let $x' = x + t' - t$.
|
||||||
|
> - Enforce $0 \leq x' < t'$.
|
||||||
|
|
||||||
|
### $\AuthSignPublic$ with $b_1 = 1 \implies \AuthSignPublic \geq 2^{254}$
|
||||||
|
|
||||||
|
In these cases, we check that $\textsf{ak}_{0..=253} < t_\mathbb{P} < 2^{126}$:
|
||||||
|
|
||||||
1. $b_1 = 1 \implies b_0 = 0.$
|
1. $b_1 = 1 \implies b_0 = 0.$
|
||||||
Since $b_1 = 1 \implies \textsf{ak}_{0..=253} < 2^{126},$ we know that $\textsf{ak}_{126..=253} = 0,$ and in particular $b_0 = \textsf{ak}_{250..=253} = 0.$ So, we constrain $$b_1 \cdot b_0 = 0.$$
|
|
||||||
|
Since $b_1 = 1 \implies \AuthSignPublic_{0..=253} < 2^{126},$ we know that
|
||||||
|
$\AuthSignPublic_{126..=253} = 0,$ and in particular
|
||||||
|
$$b_0 := \AuthSignPublic_{250..=253} = 0.$$
|
||||||
|
|
||||||
2. $b_1 = 1 \implies 0 \leq a < 2^{126}.$
|
2. $b_1 = 1 \implies 0 \leq a < 2^{126}.$
|
||||||
|
|
||||||
To check that $a < 2^{126}$, we use two constraints:
|
To check that $a < 2^{126}$, we use two constraints:
|
||||||
|
|
||||||
a) $0 \leq a < 2^{130}$. This is expressed in the custom gate as $$b_1 \cdot z_{13,a} = 0,$$ where $z_{13,a}$ is the index-13 running sum output by $\textsf{SinsemillaHash}(a).$
|
a) $0 \leq a < 2^{130}$. This is expressed in the custom gate as
|
||||||
|
$$b_1 \cdot z_{a,13} = 0,$$
|
||||||
|
where $z_{a,13}$ is the index-13 running sum output by $\SinsemillaHash(a).$
|
||||||
|
|
||||||
b) $0 \leq a + 2^{130} - t_p < 2^{130}$. To check this, we decompose $a' = a + 2^{130} - t_p$ into thirteen 10-bit words (little-endian) using a running sum $z_{a'}$, looking up each word in a $10$-bit lookup table. We then enforce in the custom gate that $$b_1 \cdot z_{13, a'} = 0.$$
|
b) $0 \leq a + 2^{130} - t_\mathbb{P} < 2^{130}$. To check this, we decompose
|
||||||
|
$a' = a + 2^{130} - t_\mathbb{P}$ into thirteen 10-bit words (little-endian) using
|
||||||
|
a running sum $z_{a'}$, looking up each word in a $10$-bit lookup table. We then
|
||||||
|
enforce in the custom gate that
|
||||||
|
$$b_1 \cdot z_{a',13} = 0.$$
|
||||||
|
|
||||||
### $\textsf{nk} = b_2 (5 \text{ bits}) || c (240 \text{ bits}) || d_0 (9 \text{ bits}) || d_1 (1 \text{ bit})$
|
$$
|
||||||
We check that $\mathsf{I2LEBSP}_{\ell_{\textsf{base}}^{\textsf{Orchard}}}(nk)$ is a canonically-encoded $255$-bit value, i.e. $\textsf{nk} < p$. If the high bit is not set $d_1 = 0$, we are guaranteed that $nk < 2^{254}$. Thus, we are only interested in cases when $d_1 = 1 \implies nk \geq 2^{254}$. In these cases, we check that $\textsf{nk}_{0..=253} < t_p < 2^{126}$:
|
\begin{array}{|c|l|}
|
||||||
|
\hline
|
||||||
|
\text{Degree} & \text{Constraint} \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot b_1 \cdot b_0 = 0 \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot b_1 \cdot z_{a,13} = 0 \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (a + 2^{130} - t_\mathbb{P} - a') = 0 \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot b_1 \cdot z_{a',13} = 0 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
||||||
|
### $\NullifierKey$ with $d_1 = 1 \implies \NullifierKey \geq 2^{254}$
|
||||||
|
|
||||||
|
In these cases, we check that $\textsf{nk}_{0..=253} < t_\mathbb{P} < 2^{126}$:
|
||||||
|
|
||||||
|
1. $d_1 = 1 \implies d_0 = 0.$
|
||||||
|
|
||||||
|
Since $d_1 = 1 \implies \NullifierKey_{0..=253} < 2^{126},$ we know that $\NullifierKey_{126..=253} = 0,$ and in particular $$d_0 := \NullifierKey_{245..=253} = 0.$$
|
||||||
|
|
||||||
|
2. $d_1 = 1 \implies 0 \leq b_2 + 2^5 \cdot c < 2^{126}.$
|
||||||
|
|
||||||
1. $d_1 = 1 \implies 0 \leq b_2 + 2^5 \cdot c < 2^{126}.$
|
|
||||||
To check that $0 \leq b_2 + 2^5 \cdot c < 2^{126}$, we use two constraints:
|
To check that $0 \leq b_2 + 2^5 \cdot c < 2^{126}$, we use two constraints:
|
||||||
|
|
||||||
a) $0 \leq b_2 + 2^5 \cdot c < 2^{140}$. $b_2$ is already constrained individually to be a $5$-bit value. $z_{13, c}$ is the index-13 running sum output by $\textsf{SinsemillaHash}(c).$ By constraining $$d_1 \cdot z_{13,c} = 0,$$ we constrain $b_2 + 2^5 \cdot c < 2^{135} < 2^{140}.$
|
a) $0 \leq b_2 + 2^5 \cdot c < 2^{140}$. $b_2$ is already constrained individually to
|
||||||
|
be a $5$-bit value. $z_{c,13}$ is the index-13 running sum output by
|
||||||
|
$\SinsemillaHash(c).$ By constraining $$d_1 \cdot z_{c,13} = 0,$$ we constrain
|
||||||
|
$b_2 + 2^5 \cdot c < 2^{135} < 2^{140}.$
|
||||||
|
|
||||||
b) $0 \leq b_2 + 2^5 \cdot c + 2^{140} - t_p < 2^{140}$. To check this, we decompose $b' = b_2 + 2^5 \cdot c + 2^{140} - t_p$ into fourteen 10-bit words (little-endian) using a running sum $z_{b'}$, looking up each word in a $10$-bit lookup table. We then enforce in the custom gate that $$d_1 \cdot z_{14, b'} = 0.$$
|
b) $0 \leq b_2 + 2^5 \cdot c + 2^{140} - t_\mathbb{P} < 2^{140}$. To check this, we
|
||||||
|
decompose ${b_2}c' = b_2 + 2^5 \cdot c + 2^{140} - t_\mathbb{P}$ into fourteen
|
||||||
|
10-bit words (little-endian) using a running sum $z_{{b_2}c'}$, looking up each
|
||||||
|
word in a $10$-bit lookup table. We then enforce in the custom gate that
|
||||||
|
$$d_1 \cdot z_{{b_2}c',14} = 0.$$
|
||||||
|
|
||||||
|
$$
|
||||||
|
\begin{array}{|c|l|}
|
||||||
|
\hline
|
||||||
|
\text{Degree} & \text{Constraint} \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot d_1 \cdot d_0 = 0 \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot d_1 \cdot z_{c,13} = 0 \\\hline
|
||||||
|
2 & q_\CommitIvk \cdot (b_2 + c \cdot 2^5 + 2^{140} - t_\mathbb{P} - {b_2}c') = 0 \\\hline
|
||||||
|
3 & q_\CommitIvk \cdot d_1 \cdot z_{{b_2}c',14} = 0 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
||||||
|
## Region layout
|
||||||
|
|
||||||
|
The constraints controlled by the $q_\CommitIvk$ selector are arranged across all 10
|
||||||
|
advice columns, requiring two rows.
|
||||||
|
|
||||||
|
$$
|
||||||
|
\begin{array}{|c|c|c|c|c|c|c|c|c|c|c}
|
||||||
|
& & & & & & & & & & q_\CommitIvk \\\hline
|
||||||
|
a & b & c & d & \AuthSignPublic & \NullifierKey & b_0 & b_1 & b_2 & d_0 & 0 \\\hline
|
||||||
|
d_1 & z_{a,13} & a' & z_{a',13} & z_{c,13} & {b_2}c' & z_{{b_2}c',14} & & & & 1 \\\hline
|
||||||
|
\end{array}
|
||||||
|
$$
|
||||||
|
|
Loading…
Reference in New Issue