Struct ark_ff::fields::models::fp6_2over3::Fp6ConfigWrapper

pub struct Fp6ConfigWrapper<P: Fp6Config>(_);

Trait Implementations

impl<P: Fp6Config> QuadExtConfig for Fp6ConfigWrapper<P>

type BasePrimeField = <<P as Fp6Config>::Fp3Config as Fp3Config>::Fp

The prime field that this quadratic extension is eventually an extension of.

type BaseField = CubicExtField<Fp3ConfigWrapper<<P as Fp6Config>::Fp3Config>>

The base field that this field is a quadratic extension of.

type FrobCoeff = <Fp6ConfigWrapper<P> as QuadExtConfig>::BasePrimeField

The type of the coefficients for an efficient implemntation of the Frobenius endomorphism.

const DEGREE_OVER_BASE_PRIME_FIELD: usize = 6usize

The degree of the extension over the base prime field.

const NONRESIDUE: Self::BaseField = P::NONRESIDUE

The quadratic non-residue used to construct the extension.

const FROBENIUS_COEFF_C1: &'static [Self::FrobCoeff] = P::FROBENIUS_COEFF_FP6_C1

Coefficients for the Frobenius automorphism.

fn mul_base_field_by_nonresidue_in_place( fe: &mut Self::BaseField ) -> &mut Self::BaseField

A specializable method for multiplying an element of the base field by the quadratic non-residue. This is used in Karatsuba multiplication and in complex squaring.

fn mul_base_field_by_frob_coeff(fe: &mut Self::BaseField, power: usize)

A specializable method for multiplying an element of the base field by the appropriate Frobenius coefficient.

fn mul_base_field_by_nonresidue_and_add( y: &mut Self::BaseField, x: &Self::BaseField )

A specializable method for setting y = x + NONRESIDUE * y. This allows for optimizations when the non-residue is canonically negative in the field.

fn mul_base_field_by_nonresidue_plus_one_and_add( y: &mut Self::BaseField, x: &Self::BaseField )

A specializable method for computing x + mul_base_field_by_nonresidue(y) + y This allows for optimizations when the non-residue is not -1.

fn sub_and_mul_base_field_by_nonresidue( y: &mut Self::BaseField, x: &Self::BaseField )

A specializable method for computing x - mul_base_field_by_nonresidue(y) This allows for optimizations when the non-residue is canonically negative in the field.