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|
//! Support for deriving the `Sequence` trait on structs for the purposes of
//! decoding/encoding ASN.1 `SEQUENCE` types as mapped to struct fields.
mod field;
use crate::{default_lifetime, TypeAttrs};
use field::SequenceField;
use proc_macro2::TokenStream;
use quote::quote;
use syn::{DeriveInput, GenericParam, Generics, Ident, LifetimeParam};
/// Derive the `Sequence` trait for a struct
pub(crate) struct DeriveSequence {
/// Name of the sequence struct.
ident: Ident,
/// Generics of the struct.
generics: Generics,
/// Fields of the struct.
fields: Vec<SequenceField>,
}
impl DeriveSequence {
/// Parse [`DeriveInput`].
pub fn new(input: DeriveInput) -> syn::Result<Self> {
let data = match input.data {
syn::Data::Struct(data) => data,
_ => abort!(
input.ident,
"can't derive `Sequence` on this type: only `struct` types are allowed",
),
};
let type_attrs = TypeAttrs::parse(&input.attrs)?;
let fields = data
.fields
.iter()
.map(|field| SequenceField::new(field, &type_attrs))
.collect::<syn::Result<_>>()?;
Ok(Self {
ident: input.ident,
generics: input.generics.clone(),
fields,
})
}
/// Lower the derived output into a [`TokenStream`].
pub fn to_tokens(&self) -> TokenStream {
let ident = &self.ident;
let mut generics = self.generics.clone();
// Use the first lifetime parameter as lifetime for Decode/Encode lifetime
// if none found, add one.
let lifetime = generics
.lifetimes()
.next()
.map(|lt| lt.lifetime.clone())
.unwrap_or_else(|| {
let lt = default_lifetime();
generics
.params
.insert(0, GenericParam::Lifetime(LifetimeParam::new(lt.clone())));
lt
});
// We may or may not have inserted a lifetime.
let (_, ty_generics, where_clause) = self.generics.split_for_impl();
let (impl_generics, _, _) = generics.split_for_impl();
let mut decode_body = Vec::new();
let mut decode_result = Vec::new();
let mut encoded_lengths = Vec::new();
let mut encode_fields = Vec::new();
for field in &self.fields {
decode_body.push(field.to_decode_tokens());
decode_result.push(&field.ident);
let field = field.to_encode_tokens();
encoded_lengths.push(quote!(#field.encoded_len()?));
encode_fields.push(quote!(#field.encode(writer)?;));
}
quote! {
impl #impl_generics ::der::DecodeValue<#lifetime> for #ident #ty_generics #where_clause {
fn decode_value<R: ::der::Reader<#lifetime>>(
reader: &mut R,
header: ::der::Header,
) -> ::der::Result<Self> {
use ::der::{Decode as _, DecodeValue as _, Reader as _};
reader.read_nested(header.length, |reader| {
#(#decode_body)*
Ok(Self {
#(#decode_result),*
})
})
}
}
impl #impl_generics ::der::EncodeValue for #ident #ty_generics #where_clause {
fn value_len(&self) -> ::der::Result<::der::Length> {
use ::der::Encode as _;
[
#(#encoded_lengths),*
]
.into_iter()
.try_fold(::der::Length::ZERO, |acc, len| acc + len)
}
fn encode_value(&self, writer: &mut impl ::der::Writer) -> ::der::Result<()> {
use ::der::Encode as _;
#(#encode_fields)*
Ok(())
}
}
impl #impl_generics ::der::Sequence<#lifetime> for #ident #ty_generics #where_clause {}
}
}
}
#[cfg(test)]
mod tests {
use super::DeriveSequence;
use crate::{Asn1Type, TagMode};
use syn::parse_quote;
/// X.509 SPKI `AlgorithmIdentifier`.
#[test]
fn algorithm_identifier_example() {
let input = parse_quote! {
#[derive(Sequence)]
pub struct AlgorithmIdentifier<'a> {
pub algorithm: ObjectIdentifier,
pub parameters: Option<Any<'a>>,
}
};
let ir = DeriveSequence::new(input).unwrap();
assert_eq!(ir.ident, "AlgorithmIdentifier");
assert_eq!(
ir.generics.lifetimes().next().unwrap().lifetime.to_string(),
"'a"
);
assert_eq!(ir.fields.len(), 2);
let algorithm_field = &ir.fields[0];
assert_eq!(algorithm_field.ident, "algorithm");
assert_eq!(algorithm_field.attrs.asn1_type, None);
assert_eq!(algorithm_field.attrs.context_specific, None);
assert_eq!(algorithm_field.attrs.tag_mode, TagMode::Explicit);
let parameters_field = &ir.fields[1];
assert_eq!(parameters_field.ident, "parameters");
assert_eq!(parameters_field.attrs.asn1_type, None);
assert_eq!(parameters_field.attrs.context_specific, None);
assert_eq!(parameters_field.attrs.tag_mode, TagMode::Explicit);
}
/// X.509 `SubjectPublicKeyInfo`.
#[test]
fn spki_example() {
let input = parse_quote! {
#[derive(Sequence)]
pub struct SubjectPublicKeyInfo<'a> {
pub algorithm: AlgorithmIdentifier<'a>,
#[asn1(type = "BIT STRING")]
pub subject_public_key: &'a [u8],
}
};
let ir = DeriveSequence::new(input).unwrap();
assert_eq!(ir.ident, "SubjectPublicKeyInfo");
assert_eq!(
ir.generics.lifetimes().next().unwrap().lifetime.to_string(),
"'a"
);
assert_eq!(ir.fields.len(), 2);
let algorithm_field = &ir.fields[0];
assert_eq!(algorithm_field.ident, "algorithm");
assert_eq!(algorithm_field.attrs.asn1_type, None);
assert_eq!(algorithm_field.attrs.context_specific, None);
assert_eq!(algorithm_field.attrs.tag_mode, TagMode::Explicit);
let subject_public_key_field = &ir.fields[1];
assert_eq!(subject_public_key_field.ident, "subject_public_key");
assert_eq!(
subject_public_key_field.attrs.asn1_type,
Some(Asn1Type::BitString)
);
assert_eq!(subject_public_key_field.attrs.context_specific, None);
assert_eq!(subject_public_key_field.attrs.tag_mode, TagMode::Explicit);
}
/// PKCS#8v2 `OneAsymmetricKey`.
///
/// ```text
/// OneAsymmetricKey ::= SEQUENCE {
/// version Version,
/// privateKeyAlgorithm PrivateKeyAlgorithmIdentifier,
/// privateKey PrivateKey,
/// attributes [0] Attributes OPTIONAL,
/// ...,
/// [[2: publicKey [1] PublicKey OPTIONAL ]],
/// ...
/// }
///
/// Version ::= INTEGER { v1(0), v2(1) } (v1, ..., v2)
///
/// PrivateKeyAlgorithmIdentifier ::= AlgorithmIdentifier
///
/// PrivateKey ::= OCTET STRING
///
/// Attributes ::= SET OF Attribute
///
/// PublicKey ::= BIT STRING
/// ```
#[test]
fn pkcs8_example() {
let input = parse_quote! {
#[derive(Sequence)]
pub struct OneAsymmetricKey<'a> {
pub version: u8,
pub private_key_algorithm: AlgorithmIdentifier<'a>,
#[asn1(type = "OCTET STRING")]
pub private_key: &'a [u8],
#[asn1(context_specific = "0", extensible = "true", optional = "true")]
pub attributes: Option<SetOf<Any<'a>, 1>>,
#[asn1(
context_specific = "1",
extensible = "true",
optional = "true",
type = "BIT STRING"
)]
pub public_key: Option<&'a [u8]>,
}
};
let ir = DeriveSequence::new(input).unwrap();
assert_eq!(ir.ident, "OneAsymmetricKey");
assert_eq!(
ir.generics.lifetimes().next().unwrap().lifetime.to_string(),
"'a"
);
assert_eq!(ir.fields.len(), 5);
let version_field = &ir.fields[0];
assert_eq!(version_field.ident, "version");
assert_eq!(version_field.attrs.asn1_type, None);
assert_eq!(version_field.attrs.context_specific, None);
assert_eq!(version_field.attrs.extensible, false);
assert_eq!(version_field.attrs.optional, false);
assert_eq!(version_field.attrs.tag_mode, TagMode::Explicit);
let algorithm_field = &ir.fields[1];
assert_eq!(algorithm_field.ident, "private_key_algorithm");
assert_eq!(algorithm_field.attrs.asn1_type, None);
assert_eq!(algorithm_field.attrs.context_specific, None);
assert_eq!(algorithm_field.attrs.extensible, false);
assert_eq!(algorithm_field.attrs.optional, false);
assert_eq!(algorithm_field.attrs.tag_mode, TagMode::Explicit);
let private_key_field = &ir.fields[2];
assert_eq!(private_key_field.ident, "private_key");
assert_eq!(
private_key_field.attrs.asn1_type,
Some(Asn1Type::OctetString)
);
assert_eq!(private_key_field.attrs.context_specific, None);
assert_eq!(private_key_field.attrs.extensible, false);
assert_eq!(private_key_field.attrs.optional, false);
assert_eq!(private_key_field.attrs.tag_mode, TagMode::Explicit);
let attributes_field = &ir.fields[3];
assert_eq!(attributes_field.ident, "attributes");
assert_eq!(attributes_field.attrs.asn1_type, None);
assert_eq!(
attributes_field.attrs.context_specific,
Some("0".parse().unwrap())
);
assert_eq!(attributes_field.attrs.extensible, true);
assert_eq!(attributes_field.attrs.optional, true);
assert_eq!(attributes_field.attrs.tag_mode, TagMode::Explicit);
let public_key_field = &ir.fields[4];
assert_eq!(public_key_field.ident, "public_key");
assert_eq!(public_key_field.attrs.asn1_type, Some(Asn1Type::BitString));
assert_eq!(
public_key_field.attrs.context_specific,
Some("1".parse().unwrap())
);
assert_eq!(public_key_field.attrs.extensible, true);
assert_eq!(public_key_field.attrs.optional, true);
assert_eq!(public_key_field.attrs.tag_mode, TagMode::Explicit);
}
/// `IMPLICIT` tagged example
#[test]
fn implicit_example() {
let input = parse_quote! {
#[asn1(tag_mode = "IMPLICIT")]
pub struct ImplicitSequence<'a> {
#[asn1(context_specific = "0", type = "BIT STRING")]
bit_string: BitString<'a>,
#[asn1(context_specific = "1", type = "GeneralizedTime")]
time: GeneralizedTime,
#[asn1(context_specific = "2", type = "UTF8String")]
utf8_string: String,
}
};
let ir = DeriveSequence::new(input).unwrap();
assert_eq!(ir.ident, "ImplicitSequence");
assert_eq!(
ir.generics.lifetimes().next().unwrap().lifetime.to_string(),
"'a"
);
assert_eq!(ir.fields.len(), 3);
let bit_string = &ir.fields[0];
assert_eq!(bit_string.ident, "bit_string");
assert_eq!(bit_string.attrs.asn1_type, Some(Asn1Type::BitString));
assert_eq!(
bit_string.attrs.context_specific,
Some("0".parse().unwrap())
);
assert_eq!(bit_string.attrs.tag_mode, TagMode::Implicit);
let time = &ir.fields[1];
assert_eq!(time.ident, "time");
assert_eq!(time.attrs.asn1_type, Some(Asn1Type::GeneralizedTime));
assert_eq!(time.attrs.context_specific, Some("1".parse().unwrap()));
assert_eq!(time.attrs.tag_mode, TagMode::Implicit);
let utf8_string = &ir.fields[2];
assert_eq!(utf8_string.ident, "utf8_string");
assert_eq!(utf8_string.attrs.asn1_type, Some(Asn1Type::Utf8String));
assert_eq!(
utf8_string.attrs.context_specific,
Some("2".parse().unwrap())
);
assert_eq!(utf8_string.attrs.tag_mode, TagMode::Implicit);
}
}
|
