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keygen.rs
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keygen.rs
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#![allow(clippy::int_plus_one)]
use std::ops::Range;
use ff::{Field, FromUniformBytes};
use group::Curve;
use super::{
circuit::{
Advice, Any, Assignment, Circuit, Column, ConstraintSystem, Fixed, FloorPlanner, Instance,
Selector,
},
evaluation::Evaluator,
permutation, Assigned, Challenge, Error, LagrangeCoeff, Polynomial, ProvingKey, VerifyingKey,
};
use crate::{
arithmetic::{parallelize, CurveAffine},
circuit::Value,
poly::{
batch_invert_assigned,
commitment::{Blind, Params},
EvaluationDomain,
},
};
pub(crate) fn create_domain<C, ConcreteCircuit>(
k: u32,
#[cfg(feature = "circuit-params")] params: ConcreteCircuit::Params,
) -> (
EvaluationDomain<C::Scalar>,
ConstraintSystem<C::Scalar>,
ConcreteCircuit::Config,
)
where
C: CurveAffine,
ConcreteCircuit: Circuit<C::Scalar>,
{
let mut cs = ConstraintSystem::default();
#[cfg(feature = "circuit-params")]
let config = ConcreteCircuit::configure_with_params(&mut cs, params);
#[cfg(not(feature = "circuit-params"))]
let config = ConcreteCircuit::configure(&mut cs);
let degree = cs.degree();
let domain = EvaluationDomain::new(degree as u32, k);
(domain, cs, config)
}
/// Assembly to be used in circuit synthesis.
#[derive(Debug)]
struct Assembly<F: Field> {
k: u32,
fixed: Vec<Polynomial<Assigned<F>, LagrangeCoeff>>,
permutation: permutation::keygen::Assembly,
selectors: Vec<Vec<bool>>,
// A range of available rows for assignment and copies.
usable_rows: Range<usize>,
_marker: std::marker::PhantomData<F>,
}
impl<F: Field> Assignment<F> for Assembly<F> {
fn enter_region<NR, N>(&mut self, _: N)
where
NR: Into<String>,
N: FnOnce() -> NR,
{
// Do nothing; we don't care about regions in this context.
}
fn exit_region(&mut self) {
// Do nothing; we don't care about regions in this context.
}
fn enable_selector<A, AR>(&mut self, _: A, selector: &Selector, row: usize) -> Result<(), Error>
where
A: FnOnce() -> AR,
AR: Into<String>,
{
if !self.usable_rows.contains(&row) {
return Err(Error::not_enough_rows_available(self.k));
}
self.selectors[selector.0][row] = true;
Ok(())
}
fn query_instance(&self, _: Column<Instance>, row: usize) -> Result<Value<F>, Error> {
if !self.usable_rows.contains(&row) {
return Err(Error::not_enough_rows_available(self.k));
}
// There is no instance in this context.
Ok(Value::unknown())
}
fn assign_advice<V, VR, A, AR>(
&mut self,
_: A,
_: Column<Advice>,
_: usize,
_: V,
) -> Result<(), Error>
where
V: FnOnce() -> Value<VR>,
VR: Into<Assigned<F>>,
A: FnOnce() -> AR,
AR: Into<String>,
{
// We only care about fixed columns here
Ok(())
}
fn assign_fixed<V, VR, A, AR>(
&mut self,
_: A,
column: Column<Fixed>,
row: usize,
to: V,
) -> Result<(), Error>
where
V: FnOnce() -> Value<VR>,
VR: Into<Assigned<F>>,
A: FnOnce() -> AR,
AR: Into<String>,
{
if !self.usable_rows.contains(&row) {
return Err(Error::not_enough_rows_available(self.k));
}
*self
.fixed
.get_mut(column.index())
.and_then(|v| v.get_mut(row))
.ok_or(Error::BoundsFailure)? = to().into_field().assign()?;
Ok(())
}
fn copy(
&mut self,
left_column: Column<Any>,
left_row: usize,
right_column: Column<Any>,
right_row: usize,
) -> Result<(), Error> {
if !self.usable_rows.contains(&left_row) || !self.usable_rows.contains(&right_row) {
return Err(Error::not_enough_rows_available(self.k));
}
self.permutation
.copy(left_column, left_row, right_column, right_row)
}
fn fill_from_row(
&mut self,
column: Column<Fixed>,
from_row: usize,
to: Value<Assigned<F>>,
) -> Result<(), Error> {
if !self.usable_rows.contains(&from_row) {
return Err(Error::not_enough_rows_available(self.k));
}
let col = self
.fixed
.get_mut(column.index())
.ok_or(Error::BoundsFailure)?;
let filler = to.assign()?;
for row in self.usable_rows.clone().skip(from_row) {
col[row] = filler;
}
Ok(())
}
fn get_challenge(&self, _: Challenge) -> Value<F> {
Value::unknown()
}
fn annotate_column<A, AR>(&mut self, _annotation: A, _column: Column<Any>)
where
A: FnOnce() -> AR,
AR: Into<String>,
{
// Do nothing
}
fn push_namespace<NR, N>(&mut self, _: N)
where
NR: Into<String>,
N: FnOnce() -> NR,
{
// Do nothing; we don't care about namespaces in this context.
}
fn pop_namespace(&mut self, _: Option<String>) {
// Do nothing; we don't care about namespaces in this context.
}
}
/// Generate a `VerifyingKey` from an instance of `Circuit`.
/// By default, selector compression is turned **off**.
pub fn keygen_vk<'params, C, P, ConcreteCircuit>(
params: &P,
circuit: &ConcreteCircuit,
) -> Result<VerifyingKey<C>, Error>
where
C: CurveAffine,
P: Params<'params, C>,
ConcreteCircuit: Circuit<C::Scalar>,
C::Scalar: FromUniformBytes<64>,
{
keygen_vk_custom(params, circuit, true)
}
/// Generate a `VerifyingKey` from an instance of `Circuit`.
///
/// The selector compression optimization is turned on only if `compress_selectors` is `true`.
pub fn keygen_vk_custom<'params, C, P, ConcreteCircuit>(
params: &P,
circuit: &ConcreteCircuit,
compress_selectors: bool,
) -> Result<VerifyingKey<C>, Error>
where
C: CurveAffine,
P: Params<'params, C>,
ConcreteCircuit: Circuit<C::Scalar>,
C::Scalar: FromUniformBytes<64>,
{
let (domain, cs, config) = create_domain::<C, ConcreteCircuit>(
params.k(),
#[cfg(feature = "circuit-params")]
circuit.params(),
);
if (params.n() as usize) < cs.minimum_rows() {
return Err(Error::not_enough_rows_available(params.k()));
}
let mut assembly: Assembly<C::Scalar> = Assembly {
k: params.k(),
fixed: vec![domain.empty_lagrange_assigned(); cs.num_fixed_columns],
permutation: permutation::keygen::Assembly::new(params.n() as usize, &cs.permutation),
selectors: vec![vec![false; params.n() as usize]; cs.num_selectors],
usable_rows: 0..params.n() as usize - (cs.blinding_factors() + 1),
_marker: std::marker::PhantomData,
};
// Synthesize the circuit to obtain URS
ConcreteCircuit::FloorPlanner::synthesize(
&mut assembly,
circuit,
config,
cs.constants.clone(),
)?;
let mut fixed = batch_invert_assigned(assembly.fixed);
let (cs, selector_polys) = if compress_selectors {
cs.compress_selectors(assembly.selectors.clone())
} else {
// After this, the ConstraintSystem should not have any selectors: `verify` does not need them, and `keygen_pk` regenerates `cs` from scratch anyways.
let selectors = std::mem::take(&mut assembly.selectors);
cs.directly_convert_selectors_to_fixed(selectors)
};
fixed.extend(
selector_polys
.into_iter()
.map(|poly| domain.lagrange_from_vec(poly)),
);
let permutation_vk = assembly
.permutation
.build_vk(params, &domain, &cs.permutation);
let fixed_commitments = fixed
.iter()
.map(|poly| params.commit_lagrange(poly, Blind::default()).to_affine())
.collect();
Ok(VerifyingKey::from_parts(
domain,
fixed_commitments,
permutation_vk,
cs,
assembly.selectors,
compress_selectors,
))
}
/// Generate a `ProvingKey` from a `VerifyingKey` and an instance of `Circuit`.
pub fn keygen_pk<'params, C, P, ConcreteCircuit>(
params: &P,
vk: VerifyingKey<C>,
circuit: &ConcreteCircuit,
) -> Result<ProvingKey<C>, Error>
where
C: CurveAffine,
P: Params<'params, C>,
ConcreteCircuit: Circuit<C::Scalar>,
{
let mut cs = ConstraintSystem::default();
#[cfg(feature = "circuit-params")]
let config = ConcreteCircuit::configure_with_params(&mut cs, circuit.params());
#[cfg(not(feature = "circuit-params"))]
let config = ConcreteCircuit::configure(&mut cs);
let cs = cs;
if (params.n() as usize) < cs.minimum_rows() {
return Err(Error::not_enough_rows_available(params.k()));
}
let mut assembly: Assembly<C::Scalar> = Assembly {
k: params.k(),
fixed: vec![vk.domain.empty_lagrange_assigned(); cs.num_fixed_columns],
permutation: permutation::keygen::Assembly::new(params.n() as usize, &cs.permutation),
selectors: vec![vec![false; params.n() as usize]; cs.num_selectors],
usable_rows: 0..params.n() as usize - (cs.blinding_factors() + 1),
_marker: std::marker::PhantomData,
};
// Synthesize the circuit to obtain URS
ConcreteCircuit::FloorPlanner::synthesize(
&mut assembly,
circuit,
config,
cs.constants.clone(),
)?;
let mut fixed = batch_invert_assigned(assembly.fixed);
let (cs, selector_polys) = if vk.compress_selectors {
cs.compress_selectors(assembly.selectors)
} else {
cs.directly_convert_selectors_to_fixed(assembly.selectors)
};
fixed.extend(
selector_polys
.into_iter()
.map(|poly| vk.domain.lagrange_from_vec(poly)),
);
let fixed_polys: Vec<_> = fixed
.iter()
.map(|poly| vk.domain.lagrange_to_coeff(poly.clone()))
.collect();
let fixed_cosets = fixed_polys
.iter()
.map(|poly| vk.domain.coeff_to_extended(poly.clone()))
.collect();
let permutation_pk = assembly
.permutation
.build_pk(params, &vk.domain, &cs.permutation);
// Compute l_0(X)
// TODO: this can be done more efficiently
let mut l0 = vk.domain.empty_lagrange();
l0[0] = C::Scalar::ONE;
let l0 = vk.domain.lagrange_to_coeff(l0);
let l0 = vk.domain.coeff_to_extended(l0);
// Compute l_blind(X) which evaluates to 1 for each blinding factor row
// and 0 otherwise over the domain.
let mut l_blind = vk.domain.empty_lagrange();
for evaluation in l_blind[..].iter_mut().rev().take(cs.blinding_factors()) {
*evaluation = C::Scalar::ONE;
}
let l_blind = vk.domain.lagrange_to_coeff(l_blind);
let l_blind = vk.domain.coeff_to_extended(l_blind);
// Compute l_last(X) which evaluates to 1 on the first inactive row (just
// before the blinding factors) and 0 otherwise over the domain
let mut l_last = vk.domain.empty_lagrange();
l_last[params.n() as usize - cs.blinding_factors() - 1] = C::Scalar::ONE;
let l_last = vk.domain.lagrange_to_coeff(l_last);
let l_last = vk.domain.coeff_to_extended(l_last);
// Compute l_active_row(X)
let one = C::Scalar::ONE;
let mut l_active_row = vk.domain.empty_extended();
parallelize(&mut l_active_row, |values, start| {
for (i, value) in values.iter_mut().enumerate() {
let idx = i + start;
*value = one - (l_last[idx] + l_blind[idx]);
}
});
// Compute the optimized evaluation data structure
let ev = Evaluator::new(&vk.cs);
Ok(ProvingKey {
vk,
l0,
l_last,
l_active_row,
fixed_values: fixed,
fixed_polys,
fixed_cosets,
permutation: permutation_pk,
ev,
})
}