mirror of https://github.com/zcash/halo2.git
Merge pull request #133 from zcash/patch-sinsemilla
Introduce `LookupRangeCheckConfig`s for each Sinsemilla advice column
This commit is contained in:
commit
9f1bd64fe9
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@ -3,8 +3,10 @@ use crate::circuit::gadget::{
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ecc::{self, EccInstructions},
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utilities::Var,
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};
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use halo2::{arithmetic::CurveAffine, circuit::Layouter, plonk::Error};
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use std::fmt::Debug;
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use ff::PrimeField;
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use halo2::{circuit::Layouter, plonk::Error};
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use pasta_curves::arithmetic::{CurveAffine, FieldExt};
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use std::{convert::TryInto, fmt::Debug};
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pub mod chip;
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mod message;
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@ -27,7 +29,7 @@ pub trait SinsemillaInstructions<C: CurveAffine, const K: usize, const MAX_WORDS
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///
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/// For example, in the case `K = 10`, `NUM_BITS = 255`, we can fit
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/// up to `N = 25` words in a single base field element.
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type MessagePiece;
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type MessagePiece: Clone + Debug;
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/// The x-coordinate of a point output of [`Self::hash_to_point`].
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type X;
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@ -37,37 +39,6 @@ pub trait SinsemillaInstructions<C: CurveAffine, const K: usize, const MAX_WORDS
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/// HashDomains used in this instruction.
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type HashDomains: HashDomains<C>;
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/// Witness a message in the given bitstring.
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/// Returns a vector of [`Self::MessagePiece`]s encoding the given message.
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///
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/// # Panics
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///
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/// Panics if the message length is not a multiple of `K`.
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///
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/// Panics if the message length exceeds `K * MAX_WORDS`.
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fn witness_message(
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&self,
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layouter: impl Layouter<C::Base>,
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message: Vec<Option<bool>>,
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) -> Result<Self::Message, Error>;
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/// Witnesses a message piece given a field element and the intended number of `K`-bit
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/// words it contains.
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///
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/// Returns a [`Self::MessagePiece`] encoding the given message.
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///
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/// # Panics
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///
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/// Panics if the message length is not a multiple of `K`.
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///
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/// Panics if the message length exceeds the maximum number of words
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/// that can fit in a field element.
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fn witness_message_piece_bitstring(
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&self,
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layouter: impl Layouter<C::Base>,
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message: &[Option<bool>],
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) -> Result<Self::MessagePiece, Error>;
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/// Witness a message piece given a field element. Returns a [`Self::MessagePiece`]
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/// encoding the given message.
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///
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@ -75,7 +46,7 @@ pub trait SinsemillaInstructions<C: CurveAffine, const K: usize, const MAX_WORDS
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///
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/// Panics if `num_words` exceed the maximum number of `K`-bit words that
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/// can fit into a single base field element.
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fn witness_message_piece_field(
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fn witness_message_piece(
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&self,
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layouter: impl Layouter<C::Base>,
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value: Option<C::Base>,
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@ -130,24 +101,112 @@ where
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{
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fn from_bitstring(
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chip: SinsemillaChip,
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layouter: impl Layouter<C::Base>,
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mut layouter: impl Layouter<C::Base>,
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bitstring: Vec<Option<bool>>,
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) -> Result<Self, Error> {
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let inner = chip.witness_message(layouter, bitstring)?;
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Ok(Self { chip, inner })
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// Message must be composed of `K`-bit words.
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assert_eq!(bitstring.len() % K, 0);
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// Message must have at most `MAX_WORDS` words.
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assert!(bitstring.len() / K <= MAX_WORDS);
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// Message piece must be at most `ceil(C::NUM_BITS / K)` bits
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let piece_num_words = C::Base::NUM_BITS as usize / K;
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let pieces: Result<Vec<_>, _> = bitstring
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.chunks(piece_num_words * K)
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.enumerate()
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.map(
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|(i, piece)| -> Result<MessagePiece<C, SinsemillaChip, K, MAX_WORDS>, Error> {
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MessagePiece::from_bitstring(
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chip.clone(),
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layouter.namespace(|| format!("message piece {}", i)),
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piece,
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)
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},
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)
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.collect();
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pieces.map(|pieces| Self::from_pieces(chip, pieces))
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}
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/// Constructs a message from a vector of [`MessagePiece`]s.
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///
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/// [`MessagePiece`]: SinsemillaInstructions::MessagePiece
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fn from_pieces(chip: SinsemillaChip, pieces: Vec<SinsemillaChip::MessagePiece>) -> Self {
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fn from_pieces(
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chip: SinsemillaChip,
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pieces: Vec<MessagePiece<C, SinsemillaChip, K, MAX_WORDS>>,
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) -> Self {
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Self {
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chip,
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inner: pieces.into(),
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inner: pieces
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.into_iter()
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.map(|piece| piece.inner)
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.collect::<Vec<_>>()
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.into(),
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}
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}
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}
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#[derive(Clone, Debug)]
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pub struct MessagePiece<C: CurveAffine, SinsemillaChip, const K: usize, const MAX_WORDS: usize>
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where
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SinsemillaChip: SinsemillaInstructions<C, K, MAX_WORDS> + Clone + Debug + Eq,
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{
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chip: SinsemillaChip,
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inner: SinsemillaChip::MessagePiece,
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}
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impl<C: CurveAffine, SinsemillaChip, const K: usize, const MAX_WORDS: usize>
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MessagePiece<C, SinsemillaChip, K, MAX_WORDS>
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where
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SinsemillaChip: SinsemillaInstructions<C, K, MAX_WORDS> + Clone + Debug + Eq,
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{
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fn from_bitstring(
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chip: SinsemillaChip,
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layouter: impl Layouter<C::Base>,
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bitstring: &[Option<bool>],
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) -> Result<Self, Error> {
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// Message must be composed of `K`-bit words.
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assert_eq!(bitstring.len() % K, 0);
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let num_words = bitstring.len() / K;
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// Message piece must be at most `ceil(C::Base::NUM_BITS / K)` bits
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let piece_max_num_words = C::Base::NUM_BITS as usize / K;
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assert!(num_words <= piece_max_num_words as usize);
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// Closure to parse a bitstring (little-endian) into a base field element.
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let to_base_field = |bits: &[Option<bool>]| -> Option<C::Base> {
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assert!(bits.len() <= C::Base::NUM_BITS as usize);
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let bits: Option<Vec<bool>> = bits.iter().cloned().collect();
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let bytes: Option<Vec<u8>> = bits.map(|bits| {
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// Pad bits to 256 bits
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let pad_len = 256 - bits.len();
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let mut bits = bits;
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bits.extend_from_slice(&vec![false; pad_len]);
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bits.chunks_exact(8)
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.map(|byte| byte.iter().rev().fold(0u8, |acc, bit| acc * 2 + *bit as u8))
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.collect()
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});
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bytes.map(|bytes| C::Base::from_bytes(&bytes.try_into().unwrap()).unwrap())
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};
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let piece_value = to_base_field(bitstring);
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Self::from_field_elem(chip, layouter, piece_value, num_words)
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}
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fn from_field_elem(
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chip: SinsemillaChip,
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layouter: impl Layouter<C::Base>,
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field_elem: Option<C::Base>,
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num_words: usize,
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) -> Result<Self, Error> {
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let inner = chip.witness_message_piece(layouter, field_elem, num_words)?;
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Ok(Self { chip, inner })
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}
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}
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/// A domain in which $\mathsf{SinsemillaHashToPoint}$ and $\mathsf{SinsemillaHash}$ can
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/// be used.
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#[allow(non_snake_case)]
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@ -242,7 +301,7 @@ mod tests {
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use super::{
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chip::SinsemillaHashDomains,
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chip::{SinsemillaChip, SinsemillaConfig},
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HashDomain, Message, SinsemillaInstructions,
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HashDomain, Message, MessagePiece,
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};
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use crate::{
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@ -278,12 +337,30 @@ mod tests {
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meta.advice_column(),
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];
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let constants = meta.fixed_column();
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// TODO: Replace with public inputs API
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let constants_1 = [
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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];
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let constants_2 = [
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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meta.fixed_column(),
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];
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let perm = meta.permutation(
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&advices
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.iter()
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.map(|advice| (*advice).into())
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.chain(Some(constants.into()))
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.chain(constants_1.iter().map(|fixed| (*fixed).into()))
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.chain(constants_2.iter().map(|fixed| (*fixed).into()))
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.collect::<Vec<_>>(),
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);
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@ -300,14 +377,14 @@ mod tests {
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meta,
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advices[..5].try_into().unwrap(),
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lookup,
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constants,
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constants_1,
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perm.clone(),
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);
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let config2 = SinsemillaChip::configure(
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meta,
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advices[5..].try_into().unwrap(),
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lookup,
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constants,
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constants_2,
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perm,
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);
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(ecc_config, config1, config2)
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@ -337,13 +414,17 @@ mod tests {
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// Layer 31, l = MERKLE_DEPTH_ORCHARD - 1 - layer = 0
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let l_bitstring = vec![Some(false); K];
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let l = chip1
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.witness_message_piece_bitstring(layouter.namespace(|| "l"), &l_bitstring)?;
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let l = MessagePiece::from_bitstring(
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chip1.clone(),
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layouter.namespace(|| "l"),
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&l_bitstring,
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)?;
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// Left leaf
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let left_bitstring: Vec<Option<bool>> =
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(0..250).map(|_| Some(rand::random::<bool>())).collect();
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let left = chip1.witness_message_piece_bitstring(
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let left = MessagePiece::from_bitstring(
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chip1.clone(),
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layouter.namespace(|| "left"),
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&left_bitstring,
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)?;
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@ -351,7 +432,8 @@ mod tests {
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// Right leaf
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let right_bitstring: Vec<Option<bool>> =
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(0..250).map(|_| Some(rand::random::<bool>())).collect();
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let right = chip1.witness_message_piece_bitstring(
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let right = MessagePiece::from_bitstring(
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chip1.clone(),
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layouter.namespace(|| "right"),
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&right_bitstring,
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)?;
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|
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@ -5,14 +5,13 @@ use super::{
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use crate::{
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circuit::gadget::{
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ecc::chip::EccPoint,
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utilities::{CellValue, Var},
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utilities::{lookup_range_check::LookupRangeCheckConfig, CellValue, Var},
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},
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primitives::sinsemilla::{
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self, Q_COMMIT_IVK_M_GENERATOR, Q_MERKLE_CRH, Q_NOTE_COMMITMENT_M_GENERATOR,
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},
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};
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use ff::PrimeField;
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use halo2::{
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arithmetic::{CurveAffine, FieldExt},
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circuit::{Chip, Layouter},
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|
@ -24,8 +23,6 @@ use halo2::{
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};
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use pasta_curves::pallas;
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use std::convert::TryInto;
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mod generator_table;
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pub use generator_table::get_s_by_idx;
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use generator_table::GeneratorTableConfig;
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@ -60,13 +57,19 @@ pub struct SinsemillaConfig {
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lambda_2: Column<Advice>,
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/// The lookup table where $(\mathsf{idx}, x_p, y_p)$ are loaded for the $2^K$
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/// generators of the Sinsemilla hash.
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generator_table: GeneratorTableConfig,
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pub(super) generator_table: GeneratorTableConfig,
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/// Fixed column shared by the whole circuit. This is used to load the
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/// x-coordinate of the domain $Q$, which is then constrained to equal the
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/// initial $x_a$.
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constants: Column<Fixed>,
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/// Permutation over all advice columns and the `constants` fixed column.
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perm: Permutation,
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pub(super) perm: Permutation,
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/// Configure each advice column to be able to perform lookup range checks.
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pub(super) lookup_config_0: LookupRangeCheckConfig<pallas::Base, { sinsemilla::K }>,
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pub(super) lookup_config_1: LookupRangeCheckConfig<pallas::Base, { sinsemilla::K }>,
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pub(super) lookup_config_2: LookupRangeCheckConfig<pallas::Base, { sinsemilla::K }>,
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pub(super) lookup_config_3: LookupRangeCheckConfig<pallas::Base, { sinsemilla::K }>,
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pub(super) lookup_config_4: LookupRangeCheckConfig<pallas::Base, { sinsemilla::K }>,
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}
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#[derive(Eq, PartialEq, Clone, Debug)]
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|
@ -106,7 +109,7 @@ impl SinsemillaChip {
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meta: &mut ConstraintSystem<pallas::Base>,
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advices: [Column<Advice>; 5],
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lookup: (Column<Fixed>, Column<Fixed>, Column<Fixed>),
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constants: Column<Fixed>,
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constants: [Column<Fixed>; 6], // TODO: replace with public inputs API
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perm: Permutation,
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) -> <Self as Chip<pallas::Base>>::Config {
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let config = SinsemillaConfig {
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|
@ -123,7 +126,42 @@ impl SinsemillaChip {
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table_x: lookup.1,
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table_y: lookup.2,
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},
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constants,
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constants: constants[5],
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lookup_config_0: LookupRangeCheckConfig::configure(
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meta,
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advices[0],
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constants[0],
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lookup.0,
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perm.clone(),
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),
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lookup_config_1: LookupRangeCheckConfig::configure(
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meta,
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advices[1],
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constants[1],
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lookup.0,
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perm.clone(),
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),
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lookup_config_2: LookupRangeCheckConfig::configure(
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meta,
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advices[2],
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constants[2],
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lookup.0,
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perm.clone(),
|
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),
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lookup_config_3: LookupRangeCheckConfig::configure(
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meta,
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advices[3],
|
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constants[3],
|
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lookup.0,
|
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perm.clone(),
|
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),
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lookup_config_4: LookupRangeCheckConfig::configure(
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meta,
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advices[4],
|
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constants[4],
|
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lookup.0,
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perm.clone(),
|
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),
|
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perm,
|
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};
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|
@ -225,71 +263,7 @@ impl SinsemillaInstructions<pallas::Affine, { sinsemilla::K }, { sinsemilla::C }
|
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|
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type HashDomains = SinsemillaHashDomains;
|
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|
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#[allow(non_snake_case)]
|
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fn witness_message(
|
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&self,
|
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mut layouter: impl Layouter<pallas::Base>,
|
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message: Vec<Option<bool>>,
|
||||
) -> Result<Self::Message, Error> {
|
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// Message must be composed of `K`-bit words.
|
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assert_eq!(message.len() % sinsemilla::K, 0);
|
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|
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// Message must have at most `sinsemilla::C` words.
|
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assert!(message.len() / sinsemilla::K <= sinsemilla::C);
|
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|
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// Message piece must be at most `ceil(pallas::Base::NUM_BITS / sinsemilla::K)` bits
|
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let piece_num_words = pallas::Base::NUM_BITS as usize / sinsemilla::K;
|
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let pieces: Result<Vec<_>, _> = message
|
||||
.chunks(piece_num_words * sinsemilla::K)
|
||||
.enumerate()
|
||||
.map(|(i, piece)| -> Result<Self::MessagePiece, Error> {
|
||||
self.witness_message_piece_bitstring(
|
||||
layouter.namespace(|| format!("message piece {}", i)),
|
||||
piece,
|
||||
)
|
||||
})
|
||||
.collect();
|
||||
|
||||
pieces.map(|pieces| pieces.into())
|
||||
}
|
||||
|
||||
#[allow(non_snake_case)]
|
||||
fn witness_message_piece_bitstring(
|
||||
&self,
|
||||
layouter: impl Layouter<pallas::Base>,
|
||||
message_piece: &[Option<bool>],
|
||||
) -> Result<Self::MessagePiece, Error> {
|
||||
// Message must be composed of `K`-bit words.
|
||||
assert_eq!(message_piece.len() % sinsemilla::K, 0);
|
||||
let num_words = message_piece.len() / sinsemilla::K;
|
||||
|
||||
// Message piece must be at most `ceil(C::Base::NUM_BITS / sinsemilla::K)` bits
|
||||
let piece_max_num_words = pallas::Base::NUM_BITS as usize / sinsemilla::K;
|
||||
assert!(num_words <= piece_max_num_words as usize);
|
||||
|
||||
// Closure to parse a bitstring (little-endian) into a base field element.
|
||||
let to_base_field = |bits: &[Option<bool>]| -> Option<pallas::Base> {
|
||||
assert!(bits.len() <= pallas::Base::NUM_BITS as usize);
|
||||
|
||||
let bits: Option<Vec<bool>> = bits.iter().cloned().collect();
|
||||
let bytes: Option<Vec<u8>> = bits.map(|bits| {
|
||||
// Pad bits to 256 bits
|
||||
let pad_len = 256 - bits.len();
|
||||
let mut bits = bits;
|
||||
bits.extend_from_slice(&vec![false; pad_len]);
|
||||
|
||||
bits.chunks_exact(8)
|
||||
.map(|byte| byte.iter().rev().fold(0u8, |acc, bit| acc * 2 + *bit as u8))
|
||||
.collect()
|
||||
});
|
||||
bytes.map(|bytes| pallas::Base::from_bytes(&bytes.try_into().unwrap()).unwrap())
|
||||
};
|
||||
|
||||
let piece_value = to_base_field(message_piece);
|
||||
self.witness_message_piece_field(layouter, piece_value, num_words)
|
||||
}
|
||||
|
||||
fn witness_message_piece_field(
|
||||
fn witness_message_piece(
|
||||
&self,
|
||||
mut layouter: impl Layouter<pallas::Base>,
|
||||
field_elem: Option<pallas::Base>,
|
||||
|
|
|
@ -34,25 +34,17 @@ impl<F: FieldExt + PrimeFieldBits, const K: usize, const MAX_WORDS: usize> std::
|
|||
/// cannot exceed the base field's `NUM_BITS`.
|
||||
#[derive(Copy, Clone, Debug)]
|
||||
pub struct MessagePiece<F: FieldExt, const K: usize> {
|
||||
cell: Cell,
|
||||
field_elem: Option<F>,
|
||||
cell_value: CellValue<F>,
|
||||
/// The number of K-bit words in this message piece.
|
||||
num_words: usize,
|
||||
}
|
||||
|
||||
#[allow(clippy::from_over_into)]
|
||||
impl<F: FieldExt + PrimeFieldBits, const K: usize> Into<CellValue<F>> for MessagePiece<F, K> {
|
||||
fn into(self) -> CellValue<F> {
|
||||
CellValue::new(self.cell(), self.field_elem())
|
||||
}
|
||||
}
|
||||
|
||||
impl<F: FieldExt + PrimeFieldBits, const K: usize> MessagePiece<F, K> {
|
||||
pub fn new(cell: Cell, field_elem: Option<F>, num_words: usize) -> Self {
|
||||
assert!(num_words * K < F::NUM_BITS as usize);
|
||||
let cell_value = CellValue::new(cell, field_elem);
|
||||
Self {
|
||||
cell,
|
||||
field_elem,
|
||||
cell_value,
|
||||
num_words,
|
||||
}
|
||||
}
|
||||
|
@ -62,10 +54,14 @@ impl<F: FieldExt + PrimeFieldBits, const K: usize> MessagePiece<F, K> {
|
|||
}
|
||||
|
||||
pub fn cell(&self) -> Cell {
|
||||
self.cell
|
||||
self.cell_value.cell()
|
||||
}
|
||||
|
||||
pub fn field_elem(&self) -> Option<F> {
|
||||
self.field_elem
|
||||
self.cell_value.value()
|
||||
}
|
||||
|
||||
pub fn cell_value(&self) -> CellValue<F> {
|
||||
self.cell_value
|
||||
}
|
||||
}
|
||||
|
|
Loading…
Reference in New Issue