tests/aead_tests.rs - platform/external/rust/crates/ring - Git at Google

 // Copyright 2015-2016 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.

 #![cfg(any(not(target_arch = "wasm32"), feature = "wasm32_c"))]

 #[cfg(target_arch = "wasm32")]
 use wasm_bindgen_test::{wasm_bindgen_test as test, wasm_bindgen_test_configure};

 #[cfg(target_arch = "wasm32")]
 wasm_bindgen_test_configure!(run_in_browser);

 use core::{convert::TryInto, ops::RangeFrom};
 use ring::{aead, error, test, test_file};

 /// Generate the known answer test functions for the given algorithm and test
 /// case input file, where each test is implemented by a test in `$test`.
 ///
 /// All of these tests can be run in parallel.
 macro_rules! test_known_answer {
     ( $alg:ident, $test_file:expr, [ $( $test:ident ),+, ] ) => {
         $(
             #[test]
             fn $test() {
                 test_aead(
                     &aead::$alg,
                     super::super::$test,
                     test_file!($test_file));
             }
         )+
     }
 }

 /// Generate the tests for a given algorithm.
 ///
 /// All of these tests can be run in parallel.
 macro_rules! test_aead {
     { $( { $alg:ident, $test_file:expr } ),+, } => {
         mod aead_test { // Make `cargo test aead` include these files.
             $(
                 #[allow(non_snake_case)]
                 mod $alg { // Provide a separate namespace for each algorithm's test.
                     #[cfg(not(target_arch = "wasm32"))]
                     use super::super::*;

                     #[cfg(target_arch = "wasm32")]
                     use super::super::{*, test};

                     test_known_answer!(
                         $alg,
                         $test_file,
                         [
                             less_safe_key_open_in_place,
                             less_safe_key_open_within,
                             less_safe_key_seal_in_place_append_tag,
                             less_safe_key_seal_in_place_separate_tag,
                             opening_key_open_in_place,
                             opening_key_open_within,
                             sealing_key_seal_in_place_append_tag,
                             sealing_key_seal_in_place_separate_tag,
                         ]);

                     #[test]
                     fn key_sizes() {
                         super::super::key_sizes(&aead::$alg);
                     }
                 }
             )+
         }
     }
 }

 test_aead! {
     { AES_128_GCM, "aead_aes_128_gcm_tests.txt" },
     { AES_256_GCM, "aead_aes_256_gcm_tests.txt" },
     { CHACHA20_POLY1305, "aead_chacha20_poly1305_tests.txt" },
 }

 struct KnownAnswerTestCase<'a> {
     key: &'a [u8],
     nonce: [u8; aead::NONCE_LEN],
     plaintext: &'a [u8],
     aad: aead::Aad<&'a [u8]>,
     ciphertext: &'a [u8],
     tag: &'a [u8],
 }

 fn test_aead(
     aead_alg: &'static aead::Algorithm,
     f: impl Fn(&'static aead::Algorithm, KnownAnswerTestCase) -> Result<(), error::Unspecified>,
     test_file: test::File,
 ) {
     test::run(test_file, |section, test_case| {
         assert_eq!(section, "");
         let key = test_case.consume_bytes("KEY");
         let nonce = test_case.consume_bytes("NONCE");
         let plaintext = test_case.consume_bytes("IN");
         let aad = test_case.consume_bytes("AD");
         let ct = test_case.consume_bytes("CT");
         let tag = test_case.consume_bytes("TAG");
         let error = test_case.consume_optional_string("FAILS");

         match error.as_deref() {
             Some("WRONG_NONCE_LENGTH") => {
                 assert!(matches!(
                     aead::Nonce::try_assume_unique_for_key(&nonce),
                     Err(error::Unspecified)
                 ));
                 return Ok(());
             }
             Some(unexpected) => {
                 unreachable!("unexpected error in test data: {}", unexpected);
             }
             None => {}
         };

         let test_case = KnownAnswerTestCase {
             key: &key,
             nonce: nonce.as_slice().try_into().unwrap(),
             plaintext: &plaintext,
             aad: aead::Aad::from(&aad),
             ciphertext: &ct,
             tag: &tag,
         };

         f(aead_alg, test_case)
     })
 }

 fn test_seal_append_tag<Seal>(
     tc: &KnownAnswerTestCase,
     seal: Seal,
 ) -> Result<(), error::Unspecified>
 where
     Seal: FnOnce(aead::Nonce, &mut Vec<u8>) -> Result<(), error::Unspecified>,
 {
     let mut in_out = Vec::from(tc.plaintext);
     seal(aead::Nonce::assume_unique_for_key(tc.nonce), &mut in_out)?;

     let mut expected_ciphertext_and_tag = Vec::from(tc.ciphertext);
     expected_ciphertext_and_tag.extend_from_slice(tc.tag);

     assert_eq!(in_out, expected_ciphertext_and_tag);

     Ok(())
 }

 fn test_seal_separate_tag<Seal>(
     tc: &KnownAnswerTestCase,
     seal: Seal,
 ) -> Result<(), error::Unspecified>
 where
     Seal: Fn(aead::Nonce, &mut [u8]) -> Result<aead::Tag, error::Unspecified>,
 {
     let mut in_out = Vec::from(tc.plaintext);
     let actual_tag = seal(aead::Nonce::assume_unique_for_key(tc.nonce), &mut in_out)?;
     assert_eq!(actual_tag.as_ref(), tc.tag);
     assert_eq!(in_out, tc.ciphertext);

     Ok(())
 }

 fn test_open_in_place<OpenInPlace>(
     tc: &KnownAnswerTestCase<'_>,
     open_in_place: OpenInPlace,
 ) -> Result<(), error::Unspecified>
 where
     OpenInPlace:
         for<'a> FnOnce(aead::Nonce, &'a mut [u8]) -> Result<&'a mut [u8], error::Unspecified>,
 {
     let nonce = aead::Nonce::assume_unique_for_key(tc.nonce);

     let mut in_out = Vec::from(tc.ciphertext);
     in_out.extend_from_slice(tc.tag);

     let actual_plaintext = open_in_place(nonce, &mut in_out)?;

     assert_eq!(actual_plaintext, tc.plaintext);
     assert_eq!(&in_out[..tc.plaintext.len()], tc.plaintext);
     Ok(())
 }

 fn test_open_within<OpenWithin>(
     tc: &KnownAnswerTestCase<'_>,
     open_within: OpenWithin,
 ) -> Result<(), error::Unspecified>
 where
     OpenWithin: for<'a> Fn(
         aead::Nonce,
         &'a mut [u8],
         RangeFrom<usize>,
     ) -> Result<&'a mut [u8], error::Unspecified>,
 {
     // In release builds, test all prefix lengths from 0 to 4096 bytes.
     // Debug builds are too slow for this, so for those builds, only
     // test a smaller subset.

     // TLS record headers are 5 bytes long.
     // TLS explicit nonces for AES-GCM are 8 bytes long.
     static MINIMAL_IN_PREFIX_LENS: [usize; 36] = [
         // No input prefix to overwrite; i.e. the opening is exactly
         // "in place."
         0,
         1,
         2,
         // Proposed TLS 1.3 header (no explicit nonce).
         5,
         8,
         // Probably the most common use of a non-zero `in_prefix_len`
         // would be to write a decrypted TLS record over the top of the
         // TLS header and nonce.
         5 /* record header */ + 8, /* explicit nonce */
         // The stitched AES-GCM x86-64 code works on 6-block (96 byte)
         // units. Some of the ChaCha20 code is even weirder.
         15,  // The maximum partial AES block.
         16,  // One AES block.
         17,  // One byte more than a full AES block.
         31,  // 2 AES blocks or 1 ChaCha20 block, minus 1.
         32,  // Two AES blocks, one ChaCha20 block.
         33,  // 2 AES blocks or 1 ChaCha20 block, plus 1.
         47,  // Three AES blocks - 1.
         48,  // Three AES blocks.
         49,  // Three AES blocks + 1.
         63,  // Four AES blocks or two ChaCha20 blocks, minus 1.
         64,  // Four AES blocks or two ChaCha20 blocks.
         65,  // Four AES blocks or two ChaCha20 blocks, plus 1.
         79,  // Five AES blocks, minus 1.
         80,  // Five AES blocks.
         81,  // Five AES blocks, plus 1.
         95,  // Six AES blocks or three ChaCha20 blocks, minus 1.
         96,  // Six AES blocks or three ChaCha20 blocks.
         97,  // Six AES blocks or three ChaCha20 blocks, plus 1.
         111, // Seven AES blocks, minus 1.
         112, // Seven AES blocks.
         113, // Seven AES blocks, plus 1.
         127, // Eight AES blocks or four ChaCha20 blocks, minus 1.
         128, // Eight AES blocks or four ChaCha20 blocks.
         129, // Eight AES blocks or four ChaCha20 blocks, plus 1.
         143, // Nine AES blocks, minus 1.
         144, // Nine AES blocks.
         145, // Nine AES blocks, plus 1.
         255, // 16 AES blocks or 8 ChaCha20 blocks, minus 1.
         256, // 16 AES blocks or 8 ChaCha20 blocks.
         257, // 16 AES blocks or 8 ChaCha20 blocks, plus 1.
     ];

     let mut more_comprehensive_in_prefix_lengths = [0; 4096];
     let in_prefix_lengths = if cfg!(debug_assertions) {
         &MINIMAL_IN_PREFIX_LENS[..]
     } else {
         #[allow(clippy::needless_range_loop)]
         for b in 0..more_comprehensive_in_prefix_lengths.len() {
             more_comprehensive_in_prefix_lengths[b] = b;
         }
         &more_comprehensive_in_prefix_lengths[..]
     };
     let mut in_out = vec![123u8; 4096];

     for &in_prefix_len in in_prefix_lengths.iter() {
         in_out.truncate(0);
         in_out.resize(in_prefix_len, 123);
         in_out.extend_from_slice(tc.ciphertext);
         in_out.extend_from_slice(tc.tag);

         let actual_plaintext = open_within(
             aead::Nonce::assume_unique_for_key(tc.nonce),
             &mut in_out,
             in_prefix_len..,
         )?;
         assert_eq!(actual_plaintext, tc.plaintext);
         assert_eq!(&in_out[..tc.plaintext.len()], tc.plaintext);
     }

     Ok(())
 }

 fn sealing_key_seal_in_place_append_tag(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_seal_append_tag(&tc, |nonce, in_out| {
         let mut key: aead::SealingKey<OneNonceSequence> = make_key(alg, tc.key, nonce);
         key.seal_in_place_append_tag(tc.aad, in_out)
     })
 }

 fn sealing_key_seal_in_place_separate_tag(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_seal_separate_tag(&tc, |nonce, in_out| {
         let mut key: aead::SealingKey<_> = make_key(alg, tc.key, nonce);
         key.seal_in_place_separate_tag(tc.aad, in_out)
     })
 }

 fn opening_key_open_in_place(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_open_in_place(&tc, |nonce, in_out| {
         let mut key: aead::OpeningKey<_> = make_key(alg, tc.key, nonce);
         key.open_in_place(tc.aad, in_out)
     })
 }

 fn opening_key_open_within(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_open_within(&tc, |nonce, in_out, ciphertext_and_tag| {
         let mut key: aead::OpeningKey<OneNonceSequence> = make_key(alg, tc.key, nonce);
         key.open_within(tc.aad, in_out, ciphertext_and_tag)
     })
 }

 fn less_safe_key_seal_in_place_append_tag(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_seal_append_tag(&tc, |nonce, in_out| {
         let key = make_less_safe_key(alg, tc.key);
         key.seal_in_place_append_tag(nonce, tc.aad, in_out)
     })
 }

 fn less_safe_key_open_in_place(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_open_in_place(&tc, |nonce, in_out| {
         let key = make_less_safe_key(alg, tc.key);
         key.open_in_place(nonce, tc.aad, in_out)
     })
 }

 fn less_safe_key_seal_in_place_separate_tag(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_seal_separate_tag(&tc, |nonce, in_out| {
         let key = make_less_safe_key(alg, tc.key);
         key.seal_in_place_separate_tag(nonce, tc.aad, in_out)
     })
 }

 fn less_safe_key_open_within(
     alg: &'static aead::Algorithm,
     tc: KnownAnswerTestCase,
 ) -> Result<(), error::Unspecified> {
     test_open_within(&tc, |nonce, in_out, ciphertext_and_tag| {
         let key = make_less_safe_key(alg, tc.key);
         key.open_within(nonce, tc.aad, in_out, ciphertext_and_tag)
     })
 }

 #[allow(clippy::range_plus_one)]
 fn key_sizes(aead_alg: &'static aead::Algorithm) {
     let key_len = aead_alg.key_len();
     let key_data = vec![0u8; key_len * 2];

     // Key is the right size.
     assert!(aead::UnboundKey::new(aead_alg, &key_data[..key_len]).is_ok());

     // Key is one byte too small.
     assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len - 1)]).is_err());

     // Key is one byte too large.
     assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len + 1)]).is_err());

     // Key is half the required size.
     assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len / 2)]).is_err());

     // Key is twice the required size.
     assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len * 2)]).is_err());

     // Key is empty.
     assert!(aead::UnboundKey::new(aead_alg, &[]).is_err());

     // Key is one byte.
     assert!(aead::UnboundKey::new(aead_alg, &[0]).is_err());
 }

 // Test that we reject non-standard nonce sizes.
 #[allow(clippy::range_plus_one)]
 #[test]
 fn test_aead_nonce_sizes() {
     let nonce_len = aead::NONCE_LEN;
     let nonce = vec![0u8; nonce_len * 2];

     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..nonce_len]).is_ok());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len - 1)]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len + 1)]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len / 2)]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len * 2)]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&[]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..1]).is_err());
     assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..16]).is_err()); // 128 bits.
 }

 #[allow(clippy::range_plus_one)]
 #[test]
 fn aead_chacha20_poly1305_openssh() {
     // TODO: test_aead_key_sizes(...);

     test::run(
         test_file!("aead_chacha20_poly1305_openssh_tests.txt"),
         |section, test_case| {
             assert_eq!(section, "");

             // XXX: `polyfill::convert` isn't available here.
             let key_bytes = {
                 let as_vec = test_case.consume_bytes("KEY");
                 let mut as_array = [0u8; aead::chacha20_poly1305_openssh::KEY_LEN];
                 as_array.copy_from_slice(&as_vec);
                 as_array
             };

             let sequence_number = test_case.consume_usize("SEQUENCE_NUMBER");
             assert_eq!(sequence_number as u32 as usize, sequence_number);
             let sequence_num = sequence_number as u32;
             let plaintext = test_case.consume_bytes("IN");
             let ct = test_case.consume_bytes("CT");
             let expected_tag = test_case.consume_bytes("TAG");

             // TODO: Add some tests for when things fail.
             //let error = test_case.consume_optional_string("FAILS");

             let mut tag = [0u8; aead::chacha20_poly1305_openssh::TAG_LEN];
             let mut s_in_out = plaintext.clone();
             let s_key = aead::chacha20_poly1305_openssh::SealingKey::new(&key_bytes);
             s_key.seal_in_place(sequence_num, &mut s_in_out[..], &mut tag);
             assert_eq!(&ct, &s_in_out);
             assert_eq!(&expected_tag, &tag);
             let o_key = aead::chacha20_poly1305_openssh::OpeningKey::new(&key_bytes);

             {
                 let o_result = o_key.open_in_place(sequence_num, &mut s_in_out[..], &tag);
                 assert_eq!(o_result, Ok(&plaintext[4..]));
             }
             assert_eq!(&s_in_out[..4], &ct[..4]);
             assert_eq!(&s_in_out[4..], &plaintext[4..]);

             Ok(())
         },
     );
 }

 #[test]
 fn aead_test_aad_traits() {
     test::compile_time_assert_copy::<aead::Aad<&'_ [u8]>>();
     test::compile_time_assert_eq::<aead::Aad<Vec<u8>>>(); // `!Copy`

     let aad_123 = aead::Aad::from(vec![1, 2, 3]); // `!Copy`
     assert_eq!(aad_123, aad_123.clone()); // Cover `Clone` and `PartialEq`
     assert_eq!(
         format!("{:?}", aead::Aad::from(&[1, 2, 3])),
         "Aad([1, 2, 3])"
     );
 }

 #[test]
 fn test_tag_traits() {
     test::compile_time_assert_send::<aead::Tag>();
     test::compile_time_assert_sync::<aead::Tag>();
 }

 #[test]
 fn test_aead_key_debug() {
     let key_bytes = [0; 32];
     let nonce = [0; aead::NONCE_LEN];

     let key = aead::UnboundKey::new(&aead::AES_256_GCM, &key_bytes).unwrap();
     assert_eq!(
         "UnboundKey { algorithm: AES_256_GCM }",
         format!("{:?}", key)
     );

     let sealing_key: aead::SealingKey<OneNonceSequence> = make_key(
         &aead::AES_256_GCM,
         &key_bytes,
         aead::Nonce::try_assume_unique_for_key(&nonce).unwrap(),
     );
     assert_eq!(
         "SealingKey { algorithm: AES_256_GCM }",
         format!("{:?}", sealing_key)
     );

     let opening_key: aead::OpeningKey<OneNonceSequence> = make_key(
         &aead::AES_256_GCM,
         &key_bytes,
         aead::Nonce::try_assume_unique_for_key(&nonce).unwrap(),
     );
     assert_eq!(
         "OpeningKey { algorithm: AES_256_GCM }",
         format!("{:?}", opening_key)
     );

     let key: aead::LessSafeKey = make_less_safe_key(&aead::AES_256_GCM, &key_bytes);
     assert_eq!(
         "LessSafeKey { algorithm: AES_256_GCM }",
         format!("{:?}", key)
     );
 }

 fn make_key<K: aead::BoundKey<OneNonceSequence>>(
     algorithm: &'static aead::Algorithm,
     key: &[u8],
     nonce: aead::Nonce,
 ) -> K {
     let key = aead::UnboundKey::new(algorithm, key).unwrap();
     let nonce_sequence = OneNonceSequence::new(nonce);
     K::new(key, nonce_sequence)
 }

 fn make_less_safe_key(algorithm: &'static aead::Algorithm, key: &[u8]) -> aead::LessSafeKey {
     let key = aead::UnboundKey::new(algorithm, key).unwrap();
     aead::LessSafeKey::new(key)
 }

 struct OneNonceSequence(Option<aead::Nonce>);

 impl OneNonceSequence {
     /// Constructs the sequence allowing `advance()` to be called
     /// `allowed_invocations` times.
     fn new(nonce: aead::Nonce) -> Self {
         Self(Some(nonce))
     }
 }

 impl aead::NonceSequence for OneNonceSequence {
     fn advance(&mut self) -> Result<aead::Nonce, error::Unspecified> {
         self.0.take().ok_or(error::Unspecified)
     }
 }
	// Copyright 2015-2016 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.

	#![cfg(any(not(target_arch = "wasm32"), feature = "wasm32_c"))]

	#[cfg(target_arch = "wasm32")]
	use wasm_bindgen_test::{wasm_bindgen_test as test, wasm_bindgen_test_configure};

	#[cfg(target_arch = "wasm32")]
	wasm_bindgen_test_configure!(run_in_browser);

	use core::{convert::TryInto, ops::RangeFrom};
	use ring::{aead, error, test, test_file};

	/// Generate the known answer test functions for the given algorithm and test
	/// case input file, where each test is implemented by a test in `$test`.
	///
	/// All of these tests can be run in parallel.
	macro_rules! test_known_answer {
	( $alg:ident, $test_file:expr, [ $( $test:ident ),+, ] ) => {
	$(
	#[test]
	fn $test() {
	test_aead(
	&aead::$alg,
	super::super::$test,
	test_file!($test_file));
	}
	)+
	}
	}

	/// Generate the tests for a given algorithm.
	///
	/// All of these tests can be run in parallel.
	macro_rules! test_aead {
	{ $( { $alg:ident, $test_file:expr } ),+, } => {
	mod aead_test { // Make `cargo test aead` include these files.
	$(
	#[allow(non_snake_case)]
	mod $alg { // Provide a separate namespace for each algorithm's test.
	#[cfg(not(target_arch = "wasm32"))]
	use super::super::*;

	#[cfg(target_arch = "wasm32")]
	use super::super::{*, test};

	test_known_answer!(
	$alg,
	$test_file,
	[
	less_safe_key_open_in_place,
	less_safe_key_open_within,
	less_safe_key_seal_in_place_append_tag,
	less_safe_key_seal_in_place_separate_tag,
	opening_key_open_in_place,
	opening_key_open_within,
	sealing_key_seal_in_place_append_tag,
	sealing_key_seal_in_place_separate_tag,
	]);

	#[test]
	fn key_sizes() {
	super::super::key_sizes(&aead::$alg);
	}
	}
	)+
	}
	}
	}

	test_aead! {
	{ AES_128_GCM, "aead_aes_128_gcm_tests.txt" },
	{ AES_256_GCM, "aead_aes_256_gcm_tests.txt" },
	{ CHACHA20_POLY1305, "aead_chacha20_poly1305_tests.txt" },
	}

	struct KnownAnswerTestCase<'a> {
	key: &'a [u8],
	nonce: [u8; aead::NONCE_LEN],
	plaintext: &'a [u8],
	aad: aead::Aad<&'a [u8]>,
	ciphertext: &'a [u8],
	tag: &'a [u8],
	}

	fn test_aead(
	aead_alg: &'static aead::Algorithm,
	f: impl Fn(&'static aead::Algorithm, KnownAnswerTestCase) -> Result<(), error::Unspecified>,
	test_file: test::File,
	) {
	test::run(test_file, \|section, test_case\| {
	assert_eq!(section, "");
	let key = test_case.consume_bytes("KEY");
	let nonce = test_case.consume_bytes("NONCE");
	let plaintext = test_case.consume_bytes("IN");
	let aad = test_case.consume_bytes("AD");
	let ct = test_case.consume_bytes("CT");
	let tag = test_case.consume_bytes("TAG");
	let error = test_case.consume_optional_string("FAILS");

	match error.as_deref() {
	Some("WRONG_NONCE_LENGTH") => {
	assert!(matches!(
	aead::Nonce::try_assume_unique_for_key(&nonce),
	Err(error::Unspecified)
	));
	return Ok(());
	}
	Some(unexpected) => {
	unreachable!("unexpected error in test data: {}", unexpected);
	}
	None => {}
	};

	let test_case = KnownAnswerTestCase {
	key: &key,
	nonce: nonce.as_slice().try_into().unwrap(),
	plaintext: &plaintext,
	aad: aead::Aad::from(&aad),
	ciphertext: &ct,
	tag: &tag,
	};

	f(aead_alg, test_case)
	})
	}

	fn test_seal_append_tag<Seal>(
	tc: &KnownAnswerTestCase,
	seal: Seal,
	) -> Result<(), error::Unspecified>
	where
	Seal: FnOnce(aead::Nonce, &mut Vec<u8>) -> Result<(), error::Unspecified>,
	{
	let mut in_out = Vec::from(tc.plaintext);
	seal(aead::Nonce::assume_unique_for_key(tc.nonce), &mut in_out)?;

	let mut expected_ciphertext_and_tag = Vec::from(tc.ciphertext);
	expected_ciphertext_and_tag.extend_from_slice(tc.tag);

	assert_eq!(in_out, expected_ciphertext_and_tag);

	Ok(())
	}

	fn test_seal_separate_tag<Seal>(
	tc: &KnownAnswerTestCase,
	seal: Seal,
	) -> Result<(), error::Unspecified>
	where
	Seal: Fn(aead::Nonce, &mut [u8]) -> Result<aead::Tag, error::Unspecified>,
	{
	let mut in_out = Vec::from(tc.plaintext);
	let actual_tag = seal(aead::Nonce::assume_unique_for_key(tc.nonce), &mut in_out)?;
	assert_eq!(actual_tag.as_ref(), tc.tag);
	assert_eq!(in_out, tc.ciphertext);

	Ok(())
	}

	fn test_open_in_place<OpenInPlace>(
	tc: &KnownAnswerTestCase<'_>,
	open_in_place: OpenInPlace,
	) -> Result<(), error::Unspecified>
	where
	OpenInPlace:
	for<'a> FnOnce(aead::Nonce, &'a mut [u8]) -> Result<&'a mut [u8], error::Unspecified>,
	{
	let nonce = aead::Nonce::assume_unique_for_key(tc.nonce);

	let mut in_out = Vec::from(tc.ciphertext);
	in_out.extend_from_slice(tc.tag);

	let actual_plaintext = open_in_place(nonce, &mut in_out)?;

	assert_eq!(actual_plaintext, tc.plaintext);
	assert_eq!(&in_out[..tc.plaintext.len()], tc.plaintext);
	Ok(())
	}

	fn test_open_within<OpenWithin>(
	tc: &KnownAnswerTestCase<'_>,
	open_within: OpenWithin,
	) -> Result<(), error::Unspecified>
	where
	OpenWithin: for<'a> Fn(
	aead::Nonce,
	&'a mut [u8],
	RangeFrom<usize>,
	) -> Result<&'a mut [u8], error::Unspecified>,
	{
	// In release builds, test all prefix lengths from 0 to 4096 bytes.
	// Debug builds are too slow for this, so for those builds, only
	// test a smaller subset.

	// TLS record headers are 5 bytes long.
	// TLS explicit nonces for AES-GCM are 8 bytes long.
	static MINIMAL_IN_PREFIX_LENS: [usize; 36] = [
	// No input prefix to overwrite; i.e. the opening is exactly
	// "in place."
	0,
	1,
	2,
	// Proposed TLS 1.3 header (no explicit nonce).
	5,
	8,
	// Probably the most common use of a non-zero `in_prefix_len`
	// would be to write a decrypted TLS record over the top of the
	// TLS header and nonce.
	5 /* record header / + 8, / explicit nonce */
	// The stitched AES-GCM x86-64 code works on 6-block (96 byte)
	// units. Some of the ChaCha20 code is even weirder.
	15, // The maximum partial AES block.
	16, // One AES block.
	17, // One byte more than a full AES block.
	31, // 2 AES blocks or 1 ChaCha20 block, minus 1.
	32, // Two AES blocks, one ChaCha20 block.
	33, // 2 AES blocks or 1 ChaCha20 block, plus 1.
	47, // Three AES blocks - 1.
	48, // Three AES blocks.
	49, // Three AES blocks + 1.
	63, // Four AES blocks or two ChaCha20 blocks, minus 1.
	64, // Four AES blocks or two ChaCha20 blocks.
	65, // Four AES blocks or two ChaCha20 blocks, plus 1.
	79, // Five AES blocks, minus 1.
	80, // Five AES blocks.
	81, // Five AES blocks, plus 1.
	95, // Six AES blocks or three ChaCha20 blocks, minus 1.
	96, // Six AES blocks or three ChaCha20 blocks.
	97, // Six AES blocks or three ChaCha20 blocks, plus 1.
	111, // Seven AES blocks, minus 1.
	112, // Seven AES blocks.
	113, // Seven AES blocks, plus 1.
	127, // Eight AES blocks or four ChaCha20 blocks, minus 1.
	128, // Eight AES blocks or four ChaCha20 blocks.
	129, // Eight AES blocks or four ChaCha20 blocks, plus 1.
	143, // Nine AES blocks, minus 1.
	144, // Nine AES blocks.
	145, // Nine AES blocks, plus 1.
	255, // 16 AES blocks or 8 ChaCha20 blocks, minus 1.
	256, // 16 AES blocks or 8 ChaCha20 blocks.
	257, // 16 AES blocks or 8 ChaCha20 blocks, plus 1.
	];

	let mut more_comprehensive_in_prefix_lengths = [0; 4096];
	let in_prefix_lengths = if cfg!(debug_assertions) {
	&MINIMAL_IN_PREFIX_LENS[..]
	} else {
	#[allow(clippy::needless_range_loop)]
	for b in 0..more_comprehensive_in_prefix_lengths.len() {
	more_comprehensive_in_prefix_lengths[b] = b;
	}
	&more_comprehensive_in_prefix_lengths[..]
	};
	let mut in_out = vec![123u8; 4096];

	for &in_prefix_len in in_prefix_lengths.iter() {
	in_out.truncate(0);
	in_out.resize(in_prefix_len, 123);
	in_out.extend_from_slice(tc.ciphertext);
	in_out.extend_from_slice(tc.tag);

	let actual_plaintext = open_within(
	aead::Nonce::assume_unique_for_key(tc.nonce),
	&mut in_out,
	in_prefix_len..,
	)?;
	assert_eq!(actual_plaintext, tc.plaintext);
	assert_eq!(&in_out[..tc.plaintext.len()], tc.plaintext);
	}

	Ok(())
	}

	fn sealing_key_seal_in_place_append_tag(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_seal_append_tag(&tc, \|nonce, in_out\| {
	let mut key: aead::SealingKey<OneNonceSequence> = make_key(alg, tc.key, nonce);
	key.seal_in_place_append_tag(tc.aad, in_out)
	})
	}

	fn sealing_key_seal_in_place_separate_tag(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_seal_separate_tag(&tc, \|nonce, in_out\| {
	let mut key: aead::SealingKey<_> = make_key(alg, tc.key, nonce);
	key.seal_in_place_separate_tag(tc.aad, in_out)
	})
	}

	fn opening_key_open_in_place(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_open_in_place(&tc, \|nonce, in_out\| {
	let mut key: aead::OpeningKey<_> = make_key(alg, tc.key, nonce);
	key.open_in_place(tc.aad, in_out)
	})
	}

	fn opening_key_open_within(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_open_within(&tc, \|nonce, in_out, ciphertext_and_tag\| {
	let mut key: aead::OpeningKey<OneNonceSequence> = make_key(alg, tc.key, nonce);
	key.open_within(tc.aad, in_out, ciphertext_and_tag)
	})
	}

	fn less_safe_key_seal_in_place_append_tag(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_seal_append_tag(&tc, \|nonce, in_out\| {
	let key = make_less_safe_key(alg, tc.key);
	key.seal_in_place_append_tag(nonce, tc.aad, in_out)
	})
	}

	fn less_safe_key_open_in_place(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_open_in_place(&tc, \|nonce, in_out\| {
	let key = make_less_safe_key(alg, tc.key);
	key.open_in_place(nonce, tc.aad, in_out)
	})
	}

	fn less_safe_key_seal_in_place_separate_tag(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_seal_separate_tag(&tc, \|nonce, in_out\| {
	let key = make_less_safe_key(alg, tc.key);
	key.seal_in_place_separate_tag(nonce, tc.aad, in_out)
	})
	}

	fn less_safe_key_open_within(
	alg: &'static aead::Algorithm,
	tc: KnownAnswerTestCase,
	) -> Result<(), error::Unspecified> {
	test_open_within(&tc, \|nonce, in_out, ciphertext_and_tag\| {
	let key = make_less_safe_key(alg, tc.key);
	key.open_within(nonce, tc.aad, in_out, ciphertext_and_tag)
	})
	}

	#[allow(clippy::range_plus_one)]
	fn key_sizes(aead_alg: &'static aead::Algorithm) {
	let key_len = aead_alg.key_len();
	let key_data = vec![0u8; key_len * 2];

	// Key is the right size.
	assert!(aead::UnboundKey::new(aead_alg, &key_data[..key_len]).is_ok());

	// Key is one byte too small.
	assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len - 1)]).is_err());

	// Key is one byte too large.
	assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len + 1)]).is_err());

	// Key is half the required size.
	assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len / 2)]).is_err());

	// Key is twice the required size.
	assert!(aead::UnboundKey::new(aead_alg, &key_data[..(key_len * 2)]).is_err());

	// Key is empty.
	assert!(aead::UnboundKey::new(aead_alg, &[]).is_err());

	// Key is one byte.
	assert!(aead::UnboundKey::new(aead_alg, &[0]).is_err());
	}

	// Test that we reject non-standard nonce sizes.
	#[allow(clippy::range_plus_one)]
	#[test]
	fn test_aead_nonce_sizes() {
	let nonce_len = aead::NONCE_LEN;
	let nonce = vec![0u8; nonce_len * 2];

	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..nonce_len]).is_ok());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len - 1)]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len + 1)]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len / 2)]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..(nonce_len * 2)]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&[]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..1]).is_err());
	assert!(aead::Nonce::try_assume_unique_for_key(&nonce[..16]).is_err()); // 128 bits.
	}

	#[allow(clippy::range_plus_one)]
	#[test]
	fn aead_chacha20_poly1305_openssh() {
	// TODO: test_aead_key_sizes(...);

	test::run(
	test_file!("aead_chacha20_poly1305_openssh_tests.txt"),
	\|section, test_case\| {
	assert_eq!(section, "");

	// XXX: `polyfill::convert` isn't available here.
	let key_bytes = {
	let as_vec = test_case.consume_bytes("KEY");
	let mut as_array = [0u8; aead::chacha20_poly1305_openssh::KEY_LEN];
	as_array.copy_from_slice(&as_vec);
	as_array
	};

	let sequence_number = test_case.consume_usize("SEQUENCE_NUMBER");
	assert_eq!(sequence_number as u32 as usize, sequence_number);
	let sequence_num = sequence_number as u32;
	let plaintext = test_case.consume_bytes("IN");
	let ct = test_case.consume_bytes("CT");
	let expected_tag = test_case.consume_bytes("TAG");

	// TODO: Add some tests for when things fail.
	//let error = test_case.consume_optional_string("FAILS");

	let mut tag = [0u8; aead::chacha20_poly1305_openssh::TAG_LEN];
	let mut s_in_out = plaintext.clone();
	let s_key = aead::chacha20_poly1305_openssh::SealingKey::new(&key_bytes);
	s_key.seal_in_place(sequence_num, &mut s_in_out[..], &mut tag);
	assert_eq!(&ct, &s_in_out);
	assert_eq!(&expected_tag, &tag);
	let o_key = aead::chacha20_poly1305_openssh::OpeningKey::new(&key_bytes);

	{
	let o_result = o_key.open_in_place(sequence_num, &mut s_in_out[..], &tag);
	assert_eq!(o_result, Ok(&plaintext[4..]));
	}
	assert_eq!(&s_in_out[..4], &ct[..4]);
	assert_eq!(&s_in_out[4..], &plaintext[4..]);

	Ok(())
	},
	);
	}

	#[test]
	fn aead_test_aad_traits() {
	test::compile_time_assert_copy::<aead::Aad<&'_ [u8]>>();
	test::compile_time_assert_eq::<aead::Aad<Vec<u8>>>(); // `!Copy`

	let aad_123 = aead::Aad::from(vec![1, 2, 3]); // `!Copy`
	assert_eq!(aad_123, aad_123.clone()); // Cover `Clone` and `PartialEq`
	assert_eq!(
	format!("{:?}", aead::Aad::from(&[1, 2, 3])),
	"Aad([1, 2, 3])"
	);
	}

	#[test]
	fn test_tag_traits() {
	test::compile_time_assert_send::<aead::Tag>();
	test::compile_time_assert_sync::<aead::Tag>();
	}

	#[test]
	fn test_aead_key_debug() {
	let key_bytes = [0; 32];
	let nonce = [0; aead::NONCE_LEN];

	let key = aead::UnboundKey::new(&aead::AES_256_GCM, &key_bytes).unwrap();
	assert_eq!(
	"UnboundKey { algorithm: AES_256_GCM }",
	format!("{:?}", key)
	);

	let sealing_key: aead::SealingKey<OneNonceSequence> = make_key(
	&aead::AES_256_GCM,
	&key_bytes,
	aead::Nonce::try_assume_unique_for_key(&nonce).unwrap(),
	);
	assert_eq!(
	"SealingKey { algorithm: AES_256_GCM }",
	format!("{:?}", sealing_key)
	);

	let opening_key: aead::OpeningKey<OneNonceSequence> = make_key(
	&aead::AES_256_GCM,
	&key_bytes,
	aead::Nonce::try_assume_unique_for_key(&nonce).unwrap(),
	);
	assert_eq!(
	"OpeningKey { algorithm: AES_256_GCM }",
	format!("{:?}", opening_key)
	);

	let key: aead::LessSafeKey = make_less_safe_key(&aead::AES_256_GCM, &key_bytes);
	assert_eq!(
	"LessSafeKey { algorithm: AES_256_GCM }",
	format!("{:?}", key)
	);
	}

	fn make_key<K: aead::BoundKey<OneNonceSequence>>(
	algorithm: &'static aead::Algorithm,
	key: &[u8],
	nonce: aead::Nonce,
	) -> K {
	let key = aead::UnboundKey::new(algorithm, key).unwrap();
	let nonce_sequence = OneNonceSequence::new(nonce);
	K::new(key, nonce_sequence)
	}

	fn make_less_safe_key(algorithm: &'static aead::Algorithm, key: &[u8]) -> aead::LessSafeKey {
	let key = aead::UnboundKey::new(algorithm, key).unwrap();
	aead::LessSafeKey::new(key)
	}

	struct OneNonceSequence(Option<aead::Nonce>);

	impl OneNonceSequence {
	/// Constructs the sequence allowing `advance()` to be called
	/// `allowed_invocations` times.
	fn new(nonce: aead::Nonce) -> Self {
	Self(Some(nonce))
	}
	}

	impl aead::NonceSequence for OneNonceSequence {
	fn advance(&mut self) -> Result<aead::Nonce, error::Unspecified> {
	self.0.take().ok_or(error::Unspecified)
	}
	}