use deno_core::error::AnyError; use elliptic_curve::AlgorithmParameters; use elliptic_curve::pkcs8; use elliptic_curve::pkcs8::der; use elliptic_curve::pkcs8::der::asn1::*; use elliptic_curve::pkcs8::der::Decodable as Pkcs8Decodable; use elliptic_curve::pkcs8::der::Encodable; use elliptic_curve::pkcs8::der::TagNumber; use elliptic_curve::pkcs8::AlgorithmIdentifier; use elliptic_curve::pkcs8::ObjectIdentifier; use elliptic_curve::pkcs8::PrivateKeyDocument; use elliptic_curve::pkcs8::PrivateKeyInfo; use elliptic_curve::zeroize::Zeroizing; use crate::shared::*; const VERSION: u8 = 1; const PUBLIC_KEY_TAG: TagNumber = TagNumber::new(1); pub struct ECPrivateKey<'a, C: elliptic_curve::Curve> { pub algorithm: AlgorithmIdentifier<'a>, pub private_d: elliptic_curve::FieldBytes, pub encoded_point: &'a [u8], } #[allow(dead_code)] ///todo(@sean) - to be removed in #13154 impl<'a, C> ECPrivateKey<'a, C> where C: elliptic_curve::Curve + AlgorithmParameters, { /// Create a new ECPrivateKey from a serialized private scalar and encoded public key pub fn from_private_and_public_bytes( private_d: elliptic_curve::FieldBytes, encoded_point: &'a [u8], ) -> Self { Self { private_d, encoded_point, algorithm: C::algorithm_identifier(), } } pub fn named_curve_oid(&self) -> Result { let parameters = self .algorithm .parameters .ok_or_else(|| data_error("malformed parameters"))?; Ok(parameters.oid().unwrap()) } fn internal_to_pkcs8_der(&self) -> der::Result> { // Shamelessly copied from pkcs8 crate and modified so as // to not require Arithmetic trait currently missing from p384 let secret_key_field = OctetString::new(&self.private_d)?; let public_key_bytes = &self.encoded_point; let public_key_field = ContextSpecific { tag_number: PUBLIC_KEY_TAG, value: BitString::new(public_key_bytes)?.into(), }; let der_message_fields: &[&dyn Encodable] = &[&VERSION, &secret_key_field, &public_key_field]; let encoded_len = der::message::encoded_len(der_message_fields)?.try_into()?; let mut der_message = Zeroizing::new(vec![0u8; encoded_len]); let mut encoder = der::Encoder::new(&mut der_message); encoder.message(der_message_fields)?; encoder.finish()?; Ok(der_message.to_vec()) } pub fn to_pkcs8_der(&self) -> Result { let pkcs8_der = self .internal_to_pkcs8_der() .map_err(|_| data_error("expected valid PKCS#8 data"))?; let pki = pkcs8::PrivateKeyInfo::new(C::algorithm_identifier(), pkcs8_der.as_ref()); Ok(pki.to_der()) } } impl<'a, C: elliptic_curve::Curve> TryFrom<&'a [u8]> for ECPrivateKey<'a, C> { type Error = AnyError; fn try_from(bytes: &'a [u8]) -> Result, AnyError> { let pk_info = PrivateKeyInfo::from_der(bytes) .map_err(|_| data_error("expected valid PKCS#8 data"))?; Self::try_from(pk_info) } } impl<'a, C: elliptic_curve::Curve> TryFrom> for ECPrivateKey<'a, C> { type Error = AnyError; fn try_from( pk_info: PrivateKeyInfo<'a>, ) -> Result, AnyError> { let any = der::asn1::Any::from_der(pk_info.private_key).map_err(|_| { data_error("expected valid PrivateKeyInfo private_key der") })?; if pk_info.algorithm.oid != elliptic_curve::ALGORITHM_OID { return Err(data_error("unsupported algorithm")); } any .sequence(|decoder| { // ver if decoder.uint8()? != VERSION { return Err(der::Tag::Integer.value_error()); } // private_key let priv_key = decoder.octet_string()?.as_bytes(); let mut private_d = elliptic_curve::FieldBytes::::default(); if priv_key.len() != private_d.len() { return Err(der::Tag::Sequence.value_error()); }; private_d.copy_from_slice(priv_key); let public_key = decoder .context_specific(PUBLIC_KEY_TAG)? .ok_or_else(|| { der::Tag::ContextSpecific(PUBLIC_KEY_TAG).value_error() })? .bit_string()?; Ok(Self { private_d, encoded_point: public_key.as_bytes(), algorithm: pk_info.algorithm, }) }) .map_err(|_| data_error("expected valid PrivateKeyInfo private_key der")) } }