/* -*- Mode: rust; rust-indent-offset: 4 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public *License,v.2.0.IfacopyoftheMPLwasnotdistributedwiththis
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
use byteorder::{BigEndian, NativeEndian, ReadBytesExt, WriteBytesExt}; use std::convert::TryInto;
/// Accessing fields of packed structs is unsafe (it may be undefined behavior if the field isn't /// aligned). Since we're implementing a PKCS#11 module, we already have to trust the caller not to /// give us bad data, so normally we would deal with this by adding an unsafe block. If we do that, /// though, the compiler complains that the unsafe block is unnecessary. Thus, we use this macro to /// annotate the unsafe block to silence the compiler. #[macro_export]
macro_rules! unsafe_packed_field_access {
($e:expr) => {{ #[allow(unused_unsafe)] let tmp = unsafe { $e };
tmp
}};
}
// The following ENCODED_OID_BYTES_* consist of the encoded bytes of an ASN.1 // OBJECT IDENTIFIER specifying the indicated OID (in other words, the full // tag, length, and value). #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst ENCODED_OID_BYTES_SECP256R1: &[u8] =
&[0x06, 0x08, 0x2a, 0x86, 0x48, 0xce, 0x3d, 0x03, 0x01, 0x07]; #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst ENCODED_OID_BYTES_SECP384R1: &[u8] = &[0x06, 0x05, 0x2b, 0x81, 0x04, 0x00, 0x22]; #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst ENCODED_OID_BYTES_SECP521R1: &[u8] = &[0x06, 0x05, 0x2b, 0x81, 0x04, 0x00, 0x23];
// The following OID_BYTES_* consist of the contents of the bytes of an ASN.1 // OBJECT IDENTIFIER specifying the indicated OID (in other words, just the // value, and not the tag or length). #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst OID_BYTES_SHA_256: &[u8] = &[0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01]; #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst OID_BYTES_SHA_384: &[u8] = &[0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x02]; #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst OID_BYTES_SHA_512: &[u8] = &[0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x03]; #[cfg(any(target_os = "macos", target_os = "ios"))] pubconst OID_BYTES_SHA_1: &[u8] = &[0x2b, 0x0e, 0x03, 0x02, 0x1a];
// This is a helper function to take a value and lay it out in memory how // PKCS#11 is expecting it. pubfn serialize_uint<T: TryInto<u64>>(value: T) -> Result<Vec<u8>, Error> { let value_size = std::mem::size_of::<T>(); letmut value_buf = Vec::with_capacity(value_size); let value_as_u64 = value
.try_into()
.map_err(|_| error_here!(ErrorType::ValueTooLarge))?;
value_buf
.write_uint::<NativeEndian>(value_as_u64, value_size)
.map_err(|_| error_here!(ErrorType::LibraryFailure))?;
Ok(value_buf)
}
/// Given a slice of DER bytes representing an RSA public key, extracts the bytes of the modulus /// as an unsigned integer. Also verifies that the public exponent is present (again as an /// unsigned integer). Finally verifies that reading these values consumes the entirety of the /// slice. /// RSAPublicKey ::= SEQUENCE { /// modulus INTEGER, -- n /// publicExponent INTEGER -- e /// } pubfn read_rsa_modulus(public_key: &[u8]) -> Result<Vec<u8>, Error> { letmut sequence = Sequence::new(public_key)?; let modulus_value = sequence.read_unsigned_integer()?; let _exponent = sequence.read_unsigned_integer()?; if !sequence.at_end() { return Err(error_here!(ErrorType::ExtraInput));
}
Ok(modulus_value.to_vec())
}
/// Given a slice of DER bytes representing a DigestInfo, extracts the bytes of /// the OID of the hash algorithm and the digest. /// DigestInfo ::= SEQUENCE { /// digestAlgorithm DigestAlgorithmIdentifier, /// digest Digest } /// /// DigestAlgorithmIdentifier ::= AlgorithmIdentifier /// /// AlgorithmIdentifier ::= SEQUENCE { /// algorithm OBJECT IDENTIFIER, /// parameters ANY DEFINED BY algorithm OPTIONAL } /// /// Digest ::= OCTET STRING pubfn read_digest_info(digest_info: &[u8]) -> Result<(&[u8], &[u8]), Error> { letmut sequence = Sequence::new(digest_info)?; letmut algorithm = sequence.read_sequence()?; let oid = algorithm.read_oid()?;
algorithm.read_null()?; if !algorithm.at_end() { return Err(error_here!(ErrorType::ExtraInput));
} let digest = sequence.read_octet_string()?; if !sequence.at_end() { return Err(error_here!(ErrorType::ExtraInput));
}
Ok((oid, digest))
}
/// Given a slice of DER bytes representing an ECDSA signature, extracts the bytes of `r` and `s` /// as unsigned integers. Also verifies that this consumes the entirety of the slice. /// Ecdsa-Sig-Value ::= SEQUENCE { /// r INTEGER, /// s INTEGER } #[cfg(any(target_os = "macos", target_os = "ios"))] pubfn read_ec_sig_point(signature: &[u8]) -> Result<(&[u8], &[u8]), Error> { letmut sequence = Sequence::new(signature)?; let r = sequence.read_unsigned_integer()?; let s = sequence.read_unsigned_integer()?; if !sequence.at_end() { return Err(error_here!(ErrorType::ExtraInput));
}
Ok((r, s))
}
/// Given a slice of DER bytes representing an X.509 certificate, extracts the encoded serial /// number, issuer, and subject. Does not verify that the remainder of the certificate is in any /// way well-formed. /// Certificate ::= SEQUENCE { /// tbsCertificate TBSCertificate, /// signatureAlgorithm AlgorithmIdentifier, /// signatureValue BIT STRING } /// /// TBSCertificate ::= SEQUENCE { /// version [0] EXPLICIT Version DEFAULT v1, /// serialNumber CertificateSerialNumber, /// signature AlgorithmIdentifier, /// issuer Name, /// validity Validity, /// subject Name, /// ... /// /// CertificateSerialNumber ::= INTEGER /// /// Name ::= CHOICE { -- only one possibility for now -- /// rdnSequence RDNSequence } /// /// RDNSequence ::= SEQUENCE OF RelativeDistinguishedName /// /// Validity ::= SEQUENCE { /// notBefore Time, /// notAfter Time } #[allow(clippy::type_complexity)] pubfn read_encoded_certificate_identifiers(
certificate: &[u8],
) -> Result<(Vec<u8>, Vec<u8>, Vec<u8>), Error> { letmut certificate_sequence = Sequence::new(certificate)?; letmut tbs_certificate_sequence = certificate_sequence.read_sequence()?; let _version = tbs_certificate_sequence.read_tagged_value(0)?; let serial_number = tbs_certificate_sequence.read_encoded_sequence_component(INTEGER)?; let _signature = tbs_certificate_sequence.read_sequence()?; let issuer =
tbs_certificate_sequence.read_encoded_sequence_component(SEQUENCE | CONSTRUCTED)?; let _validity = tbs_certificate_sequence.read_sequence()?; let subject =
tbs_certificate_sequence.read_encoded_sequence_component(SEQUENCE | CONSTRUCTED)?;
Ok((serial_number, issuer, subject))
}
/// Helper macro for reading some bytes from a slice while checking the slice is long enough. /// Returns a pair consisting of a slice of the bytes read and a slice of the rest of the bytes /// from the original slice.
macro_rules! try_read_bytes {
($data:ident, $len:expr) => {{ if $data.len() < $len { return Err(error_here!(ErrorType::TruncatedInput));
}
$data.split_at($len)
}};
}
/// ASN.1 tag identifying an integer. const INTEGER: u8 = 0x02; /// ASN.1 tag identifying an octet string. const OCTET_STRING: u8 = 0x04; /// ASN.1 tag identifying a null value. const NULL: u8 = 0x05; /// ASN.1 tag identifying an object identifier (OID). const OBJECT_IDENTIFIER: u8 = 0x06; /// ASN.1 tag identifying a sequence. const SEQUENCE: u8 = 0x10; /// ASN.1 tag modifier identifying an item as constructed. const CONSTRUCTED: u8 = 0x20; /// ASN.1 tag modifier identifying an item as context-specific. const CONTEXT_SPECIFIC: u8 = 0x80;
/// A helper struct for reading items from a DER SEQUENCE (in this case, all sequences are /// assumed to be CONSTRUCTED). struct Sequence<'a> { /// The contents of the SEQUENCE.
contents: Der<'a>,
}
impl<'a> Sequence<'a> { fn new(input: &'a [u8]) -> Result<Sequence<'a>, Error> { letmut der = Der::new(input); let (_, _, sequence_bytes) = der.read_tlv(SEQUENCE | CONSTRUCTED)?; // We're assuming we want to consume the entire input for now. if !der.at_end() { return Err(error_here!(ErrorType::ExtraInput));
}
Ok(Sequence {
contents: Der::new(sequence_bytes),
})
}
// TODO: we're not exhaustively validating this integer fn read_unsigned_integer(&mutself) -> Result<&'a [u8], Error> { let (_, _, bytes) = self.contents.read_tlv(INTEGER)?; if bytes.is_empty() { return Err(error_here!(ErrorType::InvalidInput));
} // There may be a leading zero (we should also check that the first bit // of the rest of the integer is set). if bytes[0] == 0 && bytes.len() > 1 { let (_, integer) = bytes.split_at(1);
Ok(integer)
} else {
Ok(bytes)
}
}
/// A helper struct for reading DER data. The contents are treated like a cursor, so its position /// is updated as data is read. struct Der<'a> {
contents: &'a [u8],
}
// In theory, a caller could encounter an error and try another operation, in which case we may // be in an inconsistent state. As long as this implementation isn't exposed to code that would // use it incorrectly (i.e. it stays in this module and we only expose a stateless API), it // should be safe. /// Given an expected tag, reads the next (tag, lengh, value) from the contents. Most /// consumers will only be interested in the value, but some may want the entire encoded /// contents, in which case the returned tuple can be concatenated. fn read_tlv(&mutself, tag: u8) -> Result<(u8, Vec<u8>, &'a [u8]), Error> { let contents = self.contents; let (tag_read, rest) = try_read_bytes!(contents, 1); if tag_read[0] != tag { return Err(error_here!(ErrorType::InvalidInput));
} letmut accumulated_length_bytes = Vec::with_capacity(4); let (length1, rest) = try_read_bytes!(rest, 1);
accumulated_length_bytes.extend_from_slice(length1); let (length, to_read_from) = if length1[0] < 0x80 {
(length1[0] as usize, rest)
} elseif length1[0] == 0x81 { let (length, rest) = try_read_bytes!(rest, 1);
accumulated_length_bytes.extend_from_slice(length); if length[0] < 0x80 { return Err(error_here!(ErrorType::InvalidInput));
}
(length[0] as usize, rest)
} elseif length1[0] == 0x82 { let (mut lengths, rest) = try_read_bytes!(rest, 2);
accumulated_length_bytes.extend_from_slice(lengths); let length = lengths
.read_u16::<BigEndian>()
.map_err(|_| error_here!(ErrorType::LibraryFailure))?; if length < 256 { return Err(error_here!(ErrorType::InvalidInput));
}
(length as usize, rest)
} else { return Err(error_here!(ErrorType::UnsupportedInput));
}; let (contents, rest) = try_read_bytes!(to_read_from, length); self.contents = rest;
Ok((tag, accumulated_length_bytes, contents))
}
#[test] fn der_test_not_shortest_two_byte_length_encoding() { let input = vec![SEQUENCE, 0x81, 1, 1]; letmut der = Der::new(&input);
assert!(der.read_tlv(SEQUENCE).is_err());
}
#[test] fn der_test_not_shortest_three_byte_length_encoding() { let input = vec![SEQUENCE, 0x82, 0, 1, 1]; letmut der = Der::new(&input);
assert!(der.read_tlv(SEQUENCE).is_err());
}
#[test] fn der_test_indefinite_length_unsupported() { let input = vec![SEQUENCE, 0x80, 1, 2, 3, 0x00, 0x00]; letmut der = Der::new(&input);
assert!(der.read_tlv(SEQUENCE).is_err());
}
#[test] fn der_test_input_too_long() { // This isn't valid DER (the contents of the SEQUENCE are truncated), but it demonstrates // that we don't try to read too much if we're given a long length (and also that we don't // support lengths 2^16 and up). let input = vec![SEQUENCE, 0x83, 0x01, 0x00, 0x01, 1, 1, 1, 1]; letmut der = Der::new(&input);
assert!(der.read_tlv(SEQUENCE).is_err());
}
#[test] fn test_read_rsa_modulus() { let rsa_key = include_bytes!("../test/rsa.bin"); let result = read_rsa_modulus(rsa_key);
assert!(result.is_ok()); let modulus = result.unwrap();
assert_eq!(modulus, include_bytes!("../test/modulus.bin").to_vec());
}
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