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// Copyright 2015-2017 Benjamin Fry <benjaminfry@me.com> // // Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or // http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or // http://opensource.org/licenses/MIT>, at your option. This file may not be // copied, modified, or distributed except according to those terms. //! TLSA records for storing TLS certificate validation information use serialize::binary::*; use error::*; /// [RFC 6698, DNS-Based Authentication for TLS](https://tools.ietf.org/html/rfc6698#section-2.1) /// /// ```text /// 2.1. TLSA RDATA Wire Format /// /// The RDATA for a TLSA RR consists of a one-octet certificate usage /// field, a one-octet selector field, a one-octet matching type field, /// and the certificate association data field. /// /// 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 3 3 /// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ /// | Cert. Usage | Selector | Matching Type | / /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ / /// / / /// / Certificate Association Data / /// / / /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ /// ``` #[derive(Debug, PartialEq, Eq, Hash, Clone)] pub struct TLSA { cert_usage: CertUsage, selector: Selector, matching: Matching, cert_data: Vec<u8>, } /// [RFC 6698, DNS-Based Authentication for TLS](https://tools.ietf.org/html/rfc6698#section-2.1.1) /// /// ```text /// 2.1.1. The Certificate Usage Field /// /// A one-octet value, called "certificate usage", specifies the provided /// association that will be used to match the certificate presented in /// the TLS handshake. This value is defined in a new IANA registry (see /// Section 7.2) in order to make it easier to add additional certificate /// usages in the future. The certificate usages defined in this /// document are: /// /// 0 -- CA /// /// 1 -- Service /// /// 2 -- TrustAnchor /// /// 3 -- DomainIssued /// /// The certificate usages defined in this document explicitly only apply /// to PKIX-formatted certificates in DER encoding [X.690]. If TLS /// allows other formats later, or if extensions to this RRtype are made /// that accept other formats for certificates, those certificates will /// need their own certificate usage values. /// ``` #[derive(Debug, PartialEq, Eq, Hash, Clone, Copy)] pub enum CertUsage { /// ```text /// 0 -- Certificate usage 0 is used to specify a CA certificate, or /// the public key of such a certificate, that MUST be found in any of /// the PKIX certification paths for the end entity certificate given /// by the server in TLS. This certificate usage is sometimes /// referred to as "CA constraint" because it limits which CA can be /// used to issue certificates for a given service on a host. The /// presented certificate MUST pass PKIX certification path /// validation, and a CA certificate that matches the TLSA record MUST /// be included as part of a valid certification path. Because this /// certificate usage allows both trust anchors and CA certificates, /// the certificate might or might not have the basicConstraints /// extension present. /// ``` CA, /// ```text /// 1 -- Certificate usage 1 is used to specify an end entity /// certificate, or the public key of such a certificate, that MUST be /// matched with the end entity certificate given by the server in /// TLS. This certificate usage is sometimes referred to as "service /// certificate constraint" because it limits which end entity /// certificate can be used by a given service on a host. The target /// certificate MUST pass PKIX certification path validation and MUST /// match the TLSA record. /// ``` Service, /// ```text /// 2 -- Certificate usage 2 is used to specify a certificate, or the /// public key of such a certificate, that MUST be used as the trust /// anchor when validating the end entity certificate given by the /// server in TLS. This certificate usage is sometimes referred to as /// "trust anchor assertion" and allows a domain name administrator to /// specify a new trust anchor -- for example, if the domain issues /// its own certificates under its own CA that is not expected to be /// in the end users' collection of trust anchors. The target /// certificate MUST pass PKIX certification path validation, with any /// certificate matching the TLSA record considered to be a trust /// anchor for this certification path validation. /// ``` TrustAnchor, /// ```text /// 3 -- Certificate usage 3 is used to specify a certificate, or the /// public key of such a certificate, that MUST match the end entity /// certificate given by the server in TLS. This certificate usage is /// sometimes referred to as "domain-issued certificate" because it /// allows for a domain name administrator to issue certificates for a /// domain without involving a third-party CA. The target certificate /// MUST match the TLSA record. The difference between certificate /// usage 1 and certificate usage 3 is that certificate usage 1 /// requires that the certificate pass PKIX validation, but PKIX /// validation is not tested for certificate usage 3. /// ``` DomainIssued, /// Unassined at the time of this implementation Unassigned(u8), /// Private usage Private, } impl From<u8> for CertUsage { fn from(usage: u8) -> Self { match usage { 0 => CertUsage::CA, 1 => CertUsage::Service, 2 => CertUsage::TrustAnchor, 3 => CertUsage::DomainIssued, 4...254 => CertUsage::Unassigned(usage), 255 => CertUsage::Private, _ => panic!("programmer error, all CertUsage variants should be covered above"), } } } impl From<CertUsage> for u8 { fn from(usage: CertUsage) -> u8 { match usage { CertUsage::CA => 0, CertUsage::Service => 1, CertUsage::TrustAnchor => 2, CertUsage::DomainIssued => 3, CertUsage::Unassigned(usage) => usage, CertUsage::Private => 255, } } } /// [RFC 6698, DNS-Based Authentication for TLS](https://tools.ietf.org/html/rfc6698#section-2.1.1) /// /// ```text /// 2.1.2. The Selector Field /// /// A one-octet value, called "selector", specifies which part of the TLS /// certificate presented by the server will be matched against the /// association data. This value is defined in a new IANA registry (see /// Section 7.3). The selectors defined in this document are: /// /// 0 -- Full /// /// 1 -- Spki /// /// (Note that the use of "selector" in this document is completely /// unrelated to the use of "selector" in DomainKeys Identified Mail /// (DKIM) [RFC6376].) /// ``` #[derive(Debug, PartialEq, Eq, Hash, Clone, Copy)] pub enum Selector { /// Full certificate: the Certificate binary structure as defined in [RFC5280] Full, /// SubjectPublicKeyInfo: DER-encoded binary structure as defined in [RFC5280] Spki, /// Unassigned at the time of this writing Unassigned(u8), /// Private usage Private, } impl From<u8> for Selector { fn from(selector: u8) -> Self { match selector { 0 => Selector::Full, 1 => Selector::Spki, 2...254 => Selector::Unassigned(selector), 255 => Selector::Private, _ => panic!("programmer error, all Selector variants should be covered above"), } } } impl From<Selector> for u8 { fn from(selector: Selector) -> u8 { match selector { Selector::Full => 0, Selector::Spki => 1, Selector::Unassigned(selector) => selector, Selector::Private => 255, } } } /// [RFC 6698, DNS-Based Authentication for TLS](https://tools.ietf.org/html/rfc6698#section-2.1.3) /// /// ```text /// 2.1.3. The Matching Type Field /// /// A one-octet value, called "matching type", specifies how the /// certificate association is presented. This value is defined in a new /// IANA registry (see Section 7.4). The types defined in this document /// are: /// /// 0 -- Raw /// /// 1 -- Sha256 /// /// 2 -- Sha512 /// /// If the TLSA record's matching type is a hash, having the record use /// the same hash algorithm that was used in the signature in the /// certificate (if possible) will assist clients that support a small /// number of hash algorithms. /// ``` #[derive(Debug, PartialEq, Eq, Hash, Clone, Copy)] pub enum Matching { /// Exact match on selected content Raw, /// SHA-256 hash of selected content [RFC6234] Sha256, /// SHA-512 hash of selected content [RFC6234] Sha512, /// Unassigned at the time of this writing Unassigned(u8), /// Private usage Private, } impl From<u8> for Matching { fn from(matching: u8) -> Self { match matching { 0 => Matching::Raw, 1 => Matching::Sha256, 2 => Matching::Sha512, 3...254 => Matching::Unassigned(matching), 255 => Matching::Private, _ => panic!("programmer error, all Matching variants should be covered above"), } } } impl From<Matching> for u8 { fn from(matching: Matching) -> u8 { match matching { Matching::Raw => 0, Matching::Sha256 => 1, Matching::Sha512 => 2, Matching::Unassigned(matching) => matching, Matching::Private => 255, } } } impl TLSA { /// Constructs a new TLSA /// /// [RFC 6698, DNS-Based Authentication for TLS](https://tools.ietf.org/html/rfc6698#section-2) /// /// ```text /// 2. The TLSA Resource Record /// /// The TLSA DNS resource record (RR) is used to associate a TLS server /// certificate or public key with the domain name where the record is /// found, thus forming a "TLSA certificate association". The semantics /// of how the TLSA RR is interpreted are given later in this document. /// /// The type value for the TLSA RR type is defined in Section 7.1. /// /// The TLSA RR is class independent. /// /// The TLSA RR has no special Time to Live (TTL) requirements. /// ``` pub fn new( cert_usage: CertUsage, selector: Selector, matching: Matching, cert_data: Vec<u8>, ) -> Self { TLSA { cert_usage, selector, matching, cert_data, } } /// Specifies the provided association that will be used to match the certificate presented in the TLS handshake pub fn cert_usage(&self) -> &CertUsage { &self.cert_usage } /// Specifies which part of the TLS certificate presented by the server will be matched against the association data pub fn selector(&self) -> &Selector { &self.selector } /// Specifies how the certificate association is presented pub fn matching(&self) -> &Matching { &self.matching } /// Binary data for validating the cert, see other members to understand format pub fn cert_data(&self) -> &[u8] { &self.cert_data } } /// Read the RData from the given Decoder /// /// ```text /// 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 3 3 /// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ /// | Cert. Usage | Selector | Matching Type | / /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ / /// / / /// / Certificate Association Data / /// / / /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ /// ``` pub fn read(decoder: &mut BinDecoder, rdata_length: u16) -> ProtoResult<TLSA> { let cert_usage = decoder.read_u8()?.into(); let selector = decoder.read_u8()?.into(); let matching = decoder.read_u8()?.into(); // the remaining data is for the cert let cert_data = decoder.read_vec((rdata_length - 3) as usize)?; Ok(TLSA { cert_usage, selector, matching, cert_data, }) } /// Write the RData from the given Decoder pub fn emit(encoder: &mut BinEncoder, tlsa: &TLSA) -> ProtoResult<()> { encoder.emit_u8(tlsa.cert_usage.into())?; encoder.emit_u8(tlsa.selector.into())?; encoder.emit_u8(tlsa.matching.into())?; encoder.emit_vec(&tlsa.cert_data)?; Ok(()) } #[cfg(test)] mod tests { use super::*; #[test] fn read_cert_usage() { assert_eq!(CertUsage::CA, CertUsage::from(0)); assert_eq!(CertUsage::Service, CertUsage::from(1)); assert_eq!(CertUsage::TrustAnchor, CertUsage::from(2)); assert_eq!(CertUsage::DomainIssued, CertUsage::from(3)); assert_eq!(CertUsage::Unassigned(4), CertUsage::from(4)); assert_eq!(CertUsage::Unassigned(254), CertUsage::from(254)); assert_eq!(CertUsage::Private, CertUsage::from(255)); assert_eq!(u8::from(CertUsage::CA), 0); assert_eq!(u8::from(CertUsage::Service), 1); assert_eq!(u8::from(CertUsage::TrustAnchor), 2); assert_eq!(u8::from(CertUsage::DomainIssued), 3); assert_eq!(u8::from(CertUsage::Unassigned(4)), 4); assert_eq!(u8::from(CertUsage::Unassigned(254)), 254); assert_eq!(u8::from(CertUsage::Private), 255); } #[test] fn read_selector() { assert_eq!(Selector::Full, Selector::from(0)); assert_eq!(Selector::Spki, Selector::from(1)); assert_eq!(Selector::Unassigned(2), Selector::from(2)); assert_eq!(Selector::Unassigned(254), Selector::from(254)); assert_eq!(Selector::Private, Selector::from(255)); assert_eq!(u8::from(Selector::Full), 0); assert_eq!(u8::from(Selector::Spki), 1); assert_eq!(u8::from(Selector::Unassigned(2)), 2); assert_eq!(u8::from(Selector::Unassigned(254)), 254); assert_eq!(u8::from(Selector::Private), 255); } #[test] fn read_matching() { assert_eq!(Matching::Raw, Matching::from(0)); assert_eq!(Matching::Sha256, Matching::from(1)); assert_eq!(Matching::Sha512, Matching::from(2)); assert_eq!(Matching::Unassigned(3), Matching::from(3)); assert_eq!(Matching::Unassigned(254), Matching::from(254)); assert_eq!(Matching::Private, Matching::from(255)); assert_eq!(u8::from(Matching::Raw), 0); assert_eq!(u8::from(Matching::Sha256), 1); assert_eq!(u8::from(Matching::Sha512), 2); assert_eq!(u8::from(Matching::Unassigned(3)), 3); assert_eq!(u8::from(Matching::Unassigned(254)), 254); assert_eq!(u8::from(Matching::Private), 255); } fn test_encode_decode(rdata: TLSA) { let mut bytes = Vec::new(); let mut encoder: BinEncoder = BinEncoder::new(&mut bytes); emit(&mut encoder, &rdata).expect("failed to emit tlsa"); let bytes = encoder.into_bytes(); println!("bytes: {:?}", bytes); let mut decoder: BinDecoder = BinDecoder::new(bytes); let read_rdata = read(&mut decoder, bytes.len() as u16).expect("failed to read back"); assert_eq!(rdata, read_rdata); } #[test] fn test_encode_decode_tlsa() { test_encode_decode(TLSA::new( CertUsage::Service, Selector::Spki, Matching::Sha256, vec![1, 2, 3, 4, 5, 6, 7, 8], )); test_encode_decode(TLSA::new( CertUsage::CA, Selector::Full, Matching::Raw, vec![1, 2, 3, 4, 5, 6, 7, 8], )); test_encode_decode(TLSA::new( CertUsage::DomainIssued, Selector::Full, Matching::Sha512, vec![1, 2, 3, 4, 5, 6, 7, 8], )); test_encode_decode(TLSA::new( CertUsage::Unassigned(40), Selector::Unassigned(39), Matching::Unassigned(6), vec![1, 2, 3, 4, 5, 6, 7, 8], )); } }