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//! Development-related functionality

pub mod curve;

// TODO(tarcieri): implement full set of tests from ECDSA2VS
// <https://csrc.nist.gov/CSRC/media/Projects/Cryptographic-Algorithm-Validation-Program/documents/dss2/ecdsa2vs.pdf>

/// ECDSA test vector
pub struct TestVector {
    /// Private scalar
    pub d: &'static [u8],

    /// Public key x-coordinate (`Qx`)
    pub q_x: &'static [u8],

    /// Public key y-coordinate (`Qy`)
    pub q_y: &'static [u8],

    /// Ephemeral scalar (a.k.a. nonce)
    pub k: &'static [u8],

    /// Message digest (prehashed)
    pub m: &'static [u8],

    /// Signature `r` component
    pub r: &'static [u8],

    /// Signature `s` component
    pub s: &'static [u8],
}

/// Define ECDSA signing test
#[macro_export]
#[cfg_attr(docsrs, doc(cfg(feature = "dev")))]
macro_rules! new_signing_test {
    ($curve:path, $vectors:expr) => {
        use core::convert::TryInto;
        use $crate::{
            elliptic_curve::{ff::PrimeField, ProjectiveArithmetic, Scalar},
            generic_array::GenericArray,
            hazmat::SignPrimitive,
        };

        #[test]
        fn ecdsa_signing() {
            for vector in $vectors {
                let d = Scalar::<$curve>::from_repr(GenericArray::clone_from_slice(vector.d))
                    .expect("invalid vector.d");

                let k = Scalar::<$curve>::from_repr(GenericArray::clone_from_slice(vector.k))
                    .expect("invalid vector.m");

                let z = Scalar::<$curve>::from_repr(GenericArray::clone_from_slice(vector.m))
                    .expect("invalid vector.z");

                let sig = d.try_sign_prehashed(&k, &z).unwrap();

                assert_eq!(vector.r, sig.r().to_bytes().as_slice());
                assert_eq!(vector.s, sig.s().to_bytes().as_slice());
            }
        }
    };
}

/// Define ECDSA verification test
#[macro_export]
#[cfg_attr(docsrs, doc(cfg(feature = "dev")))]
macro_rules! new_verification_test {
    ($curve:path, $vectors:expr) => {
        use core::convert::TryInto;
        use $crate::{
            elliptic_curve::{
                ff::PrimeField, sec1::EncodedPoint, AffinePoint, ProjectiveArithmetic, Scalar,
            },
            generic_array::GenericArray,
            hazmat::VerifyPrimitive,
            Signature,
        };

        #[test]
        fn ecdsa_verify_success() {
            for vector in $vectors {
                let q_encoded = EncodedPoint::from_affine_coordinates(
                    GenericArray::from_slice(vector.q_x),
                    GenericArray::from_slice(vector.q_y),
                    false,
                );

                let q: AffinePoint<$curve> = q_encoded.decode().unwrap();

                let z = Scalar::<$curve>::from_repr(GenericArray::clone_from_slice(vector.m))
                    .expect("invalid vector.m");

                let sig = Signature::from_scalars(
                    GenericArray::clone_from_slice(vector.r),
                    GenericArray::clone_from_slice(vector.s),
                )
                .unwrap();

                let result = q.verify_prehashed(&z, &sig);
                assert!(result.is_ok());
            }
        }

        #[test]
        fn ecdsa_verify_invalid_s() {
            for vector in $vectors {
                let q_encoded = EncodedPoint::from_affine_coordinates(
                    GenericArray::from_slice(vector.q_x),
                    GenericArray::from_slice(vector.q_y),
                    false,
                );

                let q: AffinePoint<$curve> = q_encoded.decode().unwrap();

                let z = Scalar::<$curve>::from_repr(GenericArray::clone_from_slice(vector.m))
                    .expect("invalid vector.m");

                // Flip a bit in `s`
                let mut s_tweaked = GenericArray::clone_from_slice(vector.s);
                s_tweaked[0] ^= 1;

                let sig =
                    Signature::from_scalars(GenericArray::clone_from_slice(vector.r), s_tweaked)
                        .unwrap();

                let result = q.verify_prehashed(&z, &sig);
                assert!(result.is_err());
            }
        }

        // TODO(tarcieri): test invalid Q, invalid r, invalid m
    };
}