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// Copyright 2015 Brian Smith. // // Permission to use, copy, modify, and/or distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice appear in all copies. // // THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHORS DISCLAIM ALL WARRANTIES // WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR // ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES // WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN // ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF // OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. //! webpki: Web PKI X.509 Certificate Validation. //! //! See `EndEntityCert`'s documentation for a description of the certificate //! processing steps necessary for a TLS connection. #![doc(html_root_url = "https://briansmith.org/rustdoc/")] #![cfg_attr(not(feature = "std"), no_std)] #![allow(missing_debug_implementations)] // `#[derive(...)]` uses `#[allow(unused_qualifications)]` internally. #![deny(unused_qualifications)] #![forbid( anonymous_parameters, box_pointers, missing_copy_implementations, missing_docs, trivial_casts, trivial_numeric_casts, unsafe_code, unstable_features, unused_extern_crates, unused_import_braces, unused_results, variant_size_differences, warnings )] #[cfg(all(test, not(feature = "std")))] #[macro_use] extern crate std; #[macro_use] mod der; mod calendar; mod cert; mod error; mod name; mod signed_data; mod time; #[cfg(feature = "trust_anchor_util")] pub mod trust_anchor_util; mod verify_cert; pub use error::Error; pub use name::{DNSNameRef, InvalidDNSNameError}; #[cfg(feature = "std")] pub use name::DNSName; pub use signed_data::{ SignatureAlgorithm, ECDSA_P256_SHA256, ECDSA_P256_SHA384, ECDSA_P384_SHA256, ECDSA_P384_SHA384, ED25519, RSA_PKCS1_2048_8192_SHA256, RSA_PKCS1_2048_8192_SHA384, RSA_PKCS1_2048_8192_SHA512, RSA_PKCS1_3072_8192_SHA384, RSA_PSS_2048_8192_SHA256_LEGACY_KEY, RSA_PSS_2048_8192_SHA384_LEGACY_KEY, RSA_PSS_2048_8192_SHA512_LEGACY_KEY, }; pub use time::Time; /// An end-entity certificate. /// /// Server certificate processing in a TLS connection consists of several /// steps. All of these steps are necessary: /// /// * `EndEntityCert.verify_is_valid_tls_server_cert`: Verify that the server's /// certificate is currently valid *for use by a TLS server*. /// * `EndEntityCert.verify_is_valid_for_dns_name`: Verify that the server's /// certificate is valid for the host that is being connected to. /// * `EndEntityCert.verify_signature`: Verify that the signature of server's /// `ServerKeyExchange` message is valid for the server's certificate. /// /// Client certificate processing in a TLS connection consists of analogous /// steps. All of these steps are necessary: /// /// * `EndEntityCert.verify_is_valid_tls_client_cert`: Verify that the client's /// certificate is currently valid *for use by a TLS client*. /// * `EndEntityCert.verify_is_valid_for_dns_name` or /// `EndEntityCert.verify_is_valid_for_at_least_one_dns_name`: Verify that the /// client's certificate is valid for the identity or identities used to /// identify the client. (Currently client authentication only works when the /// client is identified by one or more DNS hostnames.) /// * `EndEntityCert.verify_signature`: Verify that the client's signature in /// its `CertificateVerify` message is valid using the public key from the /// client's certificate. /// /// Although it would be less error-prone to combine all these steps into a /// single function call, some significant optimizations are possible if the /// three steps are processed separately (in parallel). It does not matter much /// which order the steps are done in, but **all of these steps must completed /// before application data is sent and before received application data is /// processed**. `EndEntityCert::from` is an inexpensive operation and is /// deterministic, so if these tasks are done in multiple threads, it is /// probably best to just call `EndEntityCert::from` multiple times (before each /// operation) for the same DER-encoded ASN.1 certificate bytes. pub struct EndEntityCert<'a> { inner: cert::Cert<'a>, } impl<'a> EndEntityCert<'a> { /// Parse the ASN.1 DER-encoded X.509 encoding of the certificate /// `cert_der`. pub fn from(cert_der: &'a [u8]) -> Result<Self, Error> { Ok(Self { inner: cert::parse_cert( untrusted::Input::from(cert_der), cert::EndEntityOrCA::EndEntity, )?, }) } /// Verifies that the end-entity certificate is valid for use by a TLS /// server. /// /// `supported_sig_algs` is the list of signature algorithms that are /// trusted for use in certificate signatures; the end-entity certificate's /// public key is not validated against this list. `trust_anchors` is the /// list of root CAs to trust. `intermediate_certs` is the sequence of /// intermediate certificates that the server sent in the TLS handshake. /// `time` is the time for which the validation is effective (usually the /// current time). pub fn verify_is_valid_tls_server_cert( &self, supported_sig_algs: &[&SignatureAlgorithm], &TLSServerTrustAnchors(trust_anchors): &TLSServerTrustAnchors, intermediate_certs: &[&[u8]], time: Time, ) -> Result<(), Error> { verify_cert::build_chain( verify_cert::EKU_SERVER_AUTH, supported_sig_algs, trust_anchors, intermediate_certs, &self.inner, time, 0, ) } /// Verifies that the end-entity certificate is valid for use by a TLS /// client. /// /// If the certificate is not valid for any of the given names then this /// fails with `Error::CertNotValidForName`. /// /// `supported_sig_algs` is the list of signature algorithms that are /// trusted for use in certificate signatures; the end-entity certificate's /// public key is not validated against this list. `trust_anchors` is the /// list of root CAs to trust. `intermediate_certs` is the sequence of /// intermediate certificates that the client sent in the TLS handshake. /// `cert` is the purported end-entity certificate of the client. `time` is /// the time for which the validation is effective (usually the current /// time). pub fn verify_is_valid_tls_client_cert( &self, supported_sig_algs: &[&SignatureAlgorithm], &TLSClientTrustAnchors(trust_anchors): &TLSClientTrustAnchors, intermediate_certs: &[&[u8]], time: Time, ) -> Result<(), Error> { verify_cert::build_chain( verify_cert::EKU_CLIENT_AUTH, supported_sig_algs, trust_anchors, intermediate_certs, &self.inner, time, 0, ) } /// Verifies that the certificate is valid for the given DNS host name. pub fn verify_is_valid_for_dns_name(&self, dns_name: DNSNameRef) -> Result<(), Error> { name::verify_cert_dns_name(&self, dns_name) } /// Verifies that the certificate is valid for at least one of the given DNS /// host names. /// /// If the certificate is not valid for any of the given names then this /// fails with `Error::CertNotValidForName`. Otherwise the DNS names for /// which the certificate is valid are returned. /// /// Requires the `std` default feature; i.e. this isn't available in /// `#![no_std]` configurations. #[cfg(feature = "std")] pub fn verify_is_valid_for_at_least_one_dns_name<'names, Names>( &self, dns_names: Names, ) -> Result<Vec<DNSNameRef<'names>>, Error> where Names: Iterator<Item = DNSNameRef<'names>>, { let result: Vec<DNSNameRef<'names>> = dns_names .filter(|n| self.verify_is_valid_for_dns_name(*n).is_ok()) .collect(); if result.is_empty() { return Err(Error::CertNotValidForName); } Ok(result) } /// Verifies the signature `signature` of message `msg` using the /// certificate's public key. /// /// `signature_alg` is the algorithm to use to /// verify the signature; the certificate's public key is verified to be /// compatible with this algorithm. /// /// For TLS 1.2, `signature` corresponds to TLS's /// `DigitallySigned.signature` and `signature_alg` corresponds to TLS's /// `DigitallySigned.algorithm` of TLS type `SignatureAndHashAlgorithm`. In /// TLS 1.2 a single `SignatureAndHashAlgorithm` may map to multiple /// `SignatureAlgorithm`s. For example, a TLS 1.2 /// `ignatureAndHashAlgorithm` of (ECDSA, SHA-256) may map to any or all /// of {`ECDSA_P256_SHA256`, `ECDSA_P384_SHA256`}, depending on how the TLS /// implementation is configured. /// /// For current TLS 1.3 drafts, `signature_alg` corresponds to TLS's /// `algorithm` fields of type `SignatureScheme`. There is (currently) a /// one-to-one correspondence between TLS 1.3's `SignatureScheme` and /// `SignatureAlgorithm`. pub fn verify_signature( &self, signature_alg: &SignatureAlgorithm, msg: &[u8], signature: &[u8], ) -> Result<(), Error> { signed_data::verify_signature( signature_alg, self.inner.spki.value(), untrusted::Input::from(msg), untrusted::Input::from(signature), ) } } /// A trust anchor (a.k.a. root CA). /// /// Traditionally, certificate verification libraries have represented trust /// anchors as full X.509 root certificates. However, those certificates /// contain a lot more data than is needed for verifying certificates. The /// `TrustAnchor` representation allows an application to store just the /// essential elements of trust anchors. The `webpki::trust_anchor_util` module /// provides functions for converting X.509 certificates to to the minimized /// `TrustAnchor` representation, either at runtime or in a build script. #[derive(Debug)] pub struct TrustAnchor<'a> { /// The value of the `subject` field of the trust anchor. pub subject: &'a [u8], /// The value of the `subjectPublicKeyInfo` field of the trust anchor. pub spki: &'a [u8], /// The value of a DER-encoded NameConstraints, containing name /// constraints to apply to the trust anchor, if any. pub name_constraints: Option<&'a [u8]>, } /// Trust anchors which may be used for authenticating servers. #[derive(Debug)] pub struct TLSServerTrustAnchors<'a>(pub &'a [TrustAnchor<'a>]); /// Trust anchors which may be used for authenticating clients. #[derive(Debug)] pub struct TLSClientTrustAnchors<'a>(pub &'a [TrustAnchor<'a>]);