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// 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. //! Testing framework. //! //! Unlike the rest of *ring*, this testing framework uses panics pretty //! liberally. It was originally designed for internal use--it drives most of //! *ring*'s internal tests, and so it is optimized for getting *ring*'s tests //! written quickly at the expense of some usability. The documentation is //! lacking. The best way to learn it is to look at some examples. The digest //! tests are the most complicated because they use named sections. Other tests //! avoid named sections and so are easier to understand. //! //! # Examples //! //! ## Writing Tests //! //! Input files look like this: //! //! ```text //! # This is a comment. //! //! HMAC = SHA1 //! Input = "My test data" //! Key = "" //! Output = 61afdecb95429ef494d61fdee15990cabf0826fc //! //! HMAC = SHA256 //! Input = "Sample message for keylen<blocklen" //! Key = 000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F //! Output = A28CF43130EE696A98F14A37678B56BCFCBDD9E5CF69717FECF5480F0EBDF790 //! ``` //! //! Test cases are separated with blank lines. Note how the bytes of the `Key` //! attribute are specified as a quoted string in the first test case and as //! hex in the second test case; you can use whichever form is more convenient //! and you can mix and match within the same file. The empty sequence of bytes //! can only be represented with the quoted string form (`""`). //! //! Here's how you would consume the test data: //! //! ```ignore //! use ring::test; //! //! test::run(test::test_file!("hmac_tests.txt"), |section, test_case| { //! assert_eq!(section, ""); // This test doesn't use named sections. //! //! let digest_alg = test_case.consume_digest_alg("HMAC"); //! let input = test_case.consume_bytes("Input"); //! let key = test_case.consume_bytes("Key"); //! let output = test_case.consume_bytes("Output"); //! //! // Do the actual testing here //! }); //! ``` //! //! Note that `consume_digest_alg` automatically maps the string "SHA1" to a //! reference to `digest::SHA1_FOR_LEGACY_USE_ONLY`, "SHA256" to //! `digest::SHA256`, etc. //! //! ## Output When a Test Fails //! //! When a test case fails, the framework automatically prints out the test //! case. If the test case failed with a panic, then the backtrace of the panic //! will be printed too. For example, let's say the failing test case looks //! like this: //! //! ```text //! Curve = P-256 //! a = 2b11cb945c8cf152ffa4c9c2b1c965b019b35d0b7626919ef0ae6cb9d232f8af //! b = 18905f76a53755c679fb732b7762251075ba95fc5fedb60179e730d418a9143c //! r = 18905f76a53755c679fb732b7762251075ba95fc5fedb60179e730d418a9143c //! ``` //! If the test fails, this will be printed (if `$RUST_BACKTRACE` is `1`): //! //! ```text //! src/example_tests.txt: Test panicked. //! Curve = P-256 //! a = 2b11cb945c8cf152ffa4c9c2b1c965b019b35d0b7626919ef0ae6cb9d232f8af //! b = 18905f76a53755c679fb732b7762251075ba95fc5fedb60179e730d418a9143c //! r = 18905f76a53755c679fb732b7762251075ba95fc5fedb60179e730d418a9143c //! thread 'example_test' panicked at 'Test failed.', src\test.rs:206 //! stack backtrace: //! 0: 0x7ff654a05c7c - std::rt::lang_start::h61f4934e780b4dfc //! 1: 0x7ff654a04f32 - std::rt::lang_start::h61f4934e780b4dfc //! 2: 0x7ff6549f505d - std::panicking::rust_panic_with_hook::hfe203e3083c2b544 //! 3: 0x7ff654a0825b - rust_begin_unwind //! 4: 0x7ff6549f63af - std::panicking::begin_panic_fmt::h484cd47786497f03 //! 5: 0x7ff654a07e9b - rust_begin_unwind //! 6: 0x7ff654a0ae95 - core::panicking::panic_fmt::h257ceb0aa351d801 //! 7: 0x7ff654a0b190 - core::panicking::panic::h4bb1497076d04ab9 //! 8: 0x7ff65496dc41 - from_file<closure> //! at C:\Users\Example\example\<core macros>:4 //! 9: 0x7ff65496d49c - example_test //! at C:\Users\Example\example\src\example.rs:652 //! 10: 0x7ff6549d192a - test::stats::Summary::new::ha139494ed2e4e01f //! 11: 0x7ff6549d51a2 - test::stats::Summary::new::ha139494ed2e4e01f //! 12: 0x7ff654a0a911 - _rust_maybe_catch_panic //! 13: 0x7ff6549d56dd - test::stats::Summary::new::ha139494ed2e4e01f //! 14: 0x7ff654a03783 - std::sys::thread::Thread::new::h2b08da6cd2517f79 //! 15: 0x7ff968518101 - BaseThreadInitThunk //! ``` //! //! Notice that the output shows the name of the data file //! (`src/example_tests.txt`), the test inputs that led to the failure, and the //! stack trace to the line in the test code that panicked: entry 9 in the //! stack trace pointing to line 652 of the file `example.rs`. #[cfg(feature = "alloc")] use alloc::{format, string::String, vec::Vec}; #[cfg(feature = "alloc")] use crate::{bits, digest, error}; #[cfg(any(feature = "std", feature = "test_logging"))] extern crate std; /// `compile_time_assert_clone::<T>();` fails to compile if `T` doesn't /// implement `Clone`. pub fn compile_time_assert_clone<T: Clone>() {} /// `compile_time_assert_copy::<T>();` fails to compile if `T` doesn't /// implement `Copy`. pub fn compile_time_assert_copy<T: Copy>() {} /// `compile_time_assert_send::<T>();` fails to compile if `T` doesn't /// implement `Send`. pub fn compile_time_assert_send<T: Send>() {} /// `compile_time_assert_sync::<T>();` fails to compile if `T` doesn't /// implement `Sync`. pub fn compile_time_assert_sync<T: Sync>() {} /// `compile_time_assert_std_error_error::<T>();` fails to compile if `T` /// doesn't implement `std::error::Error`. #[cfg(feature = "std")] pub fn compile_time_assert_std_error_error<T: std::error::Error>() {} /// A test case. A test case consists of a set of named attributes. Every /// attribute in the test case must be consumed exactly once; this helps catch /// typos and omissions. /// /// Requires the `alloc` default feature to be enabled. #[cfg(feature = "alloc")] #[derive(Debug)] pub struct TestCase { attributes: Vec<(String, String, bool)>, } #[cfg(feature = "alloc")] impl TestCase { /// Maps the string "true" to true and the string "false" to false. pub fn consume_bool(&mut self, key: &str) -> bool { match self.consume_string(key).as_ref() { "true" => true, "false" => false, s => panic!("Invalid bool value: {}", s), } } /// Maps the strings "SHA1", "SHA256", "SHA384", and "SHA512" to digest /// algorithms, maps "SHA224" to `None`, and panics on other (erroneous) /// inputs. "SHA224" is mapped to None because *ring* intentionally does /// not support SHA224, but we need to consume test vectors from NIST that /// have SHA224 vectors in them. pub fn consume_digest_alg(&mut self, key: &str) -> Option<&'static digest::Algorithm> { let name = self.consume_string(key); match name.as_ref() { "SHA1" => Some(&digest::SHA1_FOR_LEGACY_USE_ONLY), "SHA224" => None, // We actively skip SHA-224 support. "SHA256" => Some(&digest::SHA256), "SHA384" => Some(&digest::SHA384), "SHA512" => Some(&digest::SHA512), "SHA512_256" => Some(&digest::SHA512_256), _ => panic!("Unsupported digest algorithm: {}", name), } } /// Returns the value of an attribute that is encoded as a sequence of an /// even number of hex digits, or as a double-quoted UTF-8 string. The /// empty (zero-length) value is represented as "". pub fn consume_bytes(&mut self, key: &str) -> Vec<u8> { let s = self.consume_string(key); if s.starts_with('\"') { // The value is a quoted UTF-8 string. let mut bytes = Vec::with_capacity(s.as_bytes().len() - 2); let mut s = s.as_bytes().iter().skip(1); loop { let b = match s.next() { Some(b'\\') => { match s.next() { // We don't allow all octal escape sequences, only "\0" for null. Some(b'0') => 0u8, Some(b't') => b'\t', Some(b'n') => b'\n', // "\xHH" Some(b'x') => { let hi = s.next().expect("Invalid hex escape sequence in string."); let lo = s.next().expect("Invalid hex escape sequence in string."); if let (Ok(hi), Ok(lo)) = (from_hex_digit(*hi), from_hex_digit(*lo)) { (hi << 4) | lo } else { panic!("Invalid hex escape sequence in string."); } } _ => { panic!("Invalid hex escape sequence in string."); } } } Some(b'"') => { if s.next().is_some() { panic!("characters after the closing quote of a quoted string."); } break; } Some(b) => *b, None => panic!("Missing terminating '\"' in string literal."), }; bytes.push(b); } bytes } else { // The value is hex encoded. match from_hex(&s) { Ok(s) => s, Err(err_str) => { panic!("{} in {}", err_str, s); } } } } /// Returns the value of an attribute that is an integer, in decimal /// notation. pub fn consume_usize(&mut self, key: &str) -> usize { let s = self.consume_string(key); s.parse::<usize>().unwrap() } /// Returns the value of an attribute that is an integer, in decimal /// notation, as a bit length. #[cfg(feature = "alloc")] pub fn consume_usize_bits(&mut self, key: &str) -> bits::BitLength { let s = self.consume_string(key); let bits = s.parse::<usize>().unwrap(); bits::BitLength::from_usize_bits(bits) } /// Returns the raw value of an attribute, without any unquoting or /// other interpretation. pub fn consume_string(&mut self, key: &str) -> String { self.consume_optional_string(key) .unwrap_or_else(|| panic!("No attribute named \"{}\"", key)) } /// Like `consume_string()` except it returns `None` if the test case /// doesn't have the attribute. pub fn consume_optional_string(&mut self, key: &str) -> Option<String> { for (name, value, consumed) in &mut self.attributes { if key == name { if *consumed { panic!("Attribute {} was already consumed", key); } *consumed = true; return Some(value.clone()); } } None } } /// References a test input file. #[cfg(feature = "alloc")] #[macro_export] macro_rules! test_file { ($file_name:expr) => { crate::test::File { file_name: $file_name, contents: include_str!($file_name), } }; } /// A test input file. #[cfg(feature = "alloc")] pub struct File<'a> { /// The name (path) of the file. pub file_name: &'a str, /// The contents of the file. pub contents: &'a str, } /// Parses test cases out of the given file, calling `f` on each vector until /// `f` fails or until all the test vectors have been read. `f` can indicate /// failure either by returning `Err()` or by panicking. /// /// Requires the `alloc` default feature to be enabled #[cfg(feature = "alloc")] pub fn run<F>(test_file: File, mut f: F) where F: FnMut(&str, &mut TestCase) -> Result<(), error::Unspecified>, { let lines = &mut test_file.contents.lines(); let mut current_section = String::from(""); let mut failed = false; while let Some(mut test_case) = parse_test_case(&mut current_section, lines) { let result = match f(¤t_section, &mut test_case) { Ok(()) => { if !test_case .attributes .iter() .any(|&(_, _, consumed)| !consumed) { Ok(()) } else { failed = true; Err("Test didn't consume all attributes.") } } Err(error::Unspecified) => Err("Test returned Err(error::Unspecified)."), }; if result.is_err() { failed = true; } #[cfg(feature = "test_logging")] { if let Err(msg) = result { std::println!("{}: {}", test_file.file_name, msg); for (name, value, consumed) in test_case.attributes { let consumed_str = if consumed { "" } else { " (unconsumed)" }; std::println!("{}{} = {}", name, consumed_str, value); } }; } } if failed { panic!("Test failed.") } } /// Decode an string of hex digits into a sequence of bytes. The input must /// have an even number of digits. #[cfg(feature = "alloc")] pub fn from_hex(hex_str: &str) -> Result<Vec<u8>, String> { if hex_str.len() % 2 != 0 { return Err(String::from( "Hex string does not have an even number of digits", )); } let mut result = Vec::with_capacity(hex_str.len() / 2); for digits in hex_str.as_bytes().chunks(2) { let hi = from_hex_digit(digits[0])?; let lo = from_hex_digit(digits[1])?; result.push((hi * 0x10) | lo); } Ok(result) } #[cfg(feature = "alloc")] fn from_hex_digit(d: u8) -> Result<u8, String> { use core::ops::RangeInclusive; const DECIMAL: (u8, RangeInclusive<u8>) = (0, b'0'..=b'9'); const HEX_LOWER: (u8, RangeInclusive<u8>) = (10, b'a'..=b'f'); const HEX_UPPER: (u8, RangeInclusive<u8>) = (10, b'A'..=b'F'); for (offset, range) in &[DECIMAL, HEX_LOWER, HEX_UPPER] { if range.contains(&d) { return Ok(d - range.start() + offset); } } Err(format!("Invalid hex digit '{}'", d as char)) } #[cfg(feature = "alloc")] fn parse_test_case( current_section: &mut String, lines: &mut dyn Iterator<Item = &str>, ) -> Option<TestCase> { let mut attributes = Vec::new(); let mut is_first_line = true; loop { let line = lines.next(); #[cfg(feature = "test_logging")] { if let Some(text) = &line { std::println!("Line: {}", text); } } match line { // If we get to EOF when we're not in the middle of a test case, // then we're done. None if is_first_line => { return None; } // End of the file on a non-empty test cases ends the test case. None => { return Some(TestCase { attributes }); } // A blank line ends a test case if the test case isn't empty. Some(ref line) if line.is_empty() => { if !is_first_line { return Some(TestCase { attributes }); } // Ignore leading blank lines. } // Comments start with '#'; ignore them. Some(ref line) if line.starts_with('#') => (), Some(ref line) if line.starts_with('[') => { assert!(is_first_line); assert!(line.ends_with(']')); current_section.truncate(0); current_section.push_str(line); let _ = current_section.pop(); let _ = current_section.remove(0); } Some(ref line) => { is_first_line = false; let parts: Vec<&str> = line.splitn(2, " = ").collect(); if parts.len() != 2 { panic!("Syntax error: Expected Key = Value."); }; let key = parts[0].trim(); let value = parts[1].trim(); // Don't allow the value to be ommitted. An empty value can be // represented as an empty quoted string. assert_ne!(value.len(), 0); // Checking is_none() ensures we don't accept duplicate keys. attributes.push((String::from(key), String::from(value), false)); } } } } /// Deterministic implementations of `ring::rand::SecureRandom`. /// /// These implementations are particularly useful for testing implementations /// of randomized algorithms & protocols using known-answer-tests where the /// test vectors contain the random seed to use. They are also especially /// useful for some types of fuzzing. #[doc(hidden)] pub mod rand { use crate::{error, polyfill, rand}; /// An implementation of `SecureRandom` that always fills the output slice /// with the given byte. #[derive(Debug)] pub struct FixedByteRandom { pub byte: u8, } impl rand::sealed::SecureRandom for FixedByteRandom { fn fill_impl(&self, dest: &mut [u8]) -> Result<(), error::Unspecified> { polyfill::slice::fill(dest, self.byte); Ok(()) } } /// An implementation of `SecureRandom` that always fills the output slice /// with the slice in `bytes`. The length of the slice given to `slice` /// must match exactly. #[derive(Debug)] pub struct FixedSliceRandom<'a> { pub bytes: &'a [u8], } impl rand::sealed::SecureRandom for FixedSliceRandom<'_> { fn fill_impl(&self, dest: &mut [u8]) -> Result<(), error::Unspecified> { dest.copy_from_slice(self.bytes); Ok(()) } } /// An implementation of `SecureRandom` where each slice in `bytes` is a /// test vector for one call to `fill()`. *Not thread-safe.* /// /// The first slice in `bytes` is the output for the first call to /// `fill()`, the second slice is the output for the second call to /// `fill()`, etc. The output slice passed to `fill()` must have exactly /// the length of the corresponding entry in `bytes`. `current` must be /// initialized to zero. `fill()` must be called exactly once for each /// entry in `bytes`. #[derive(Debug)] pub struct FixedSliceSequenceRandom<'a> { /// The value. pub bytes: &'a [&'a [u8]], pub current: core::cell::UnsafeCell<usize>, } impl rand::sealed::SecureRandom for FixedSliceSequenceRandom<'_> { fn fill_impl(&self, dest: &mut [u8]) -> Result<(), error::Unspecified> { let current = unsafe { *self.current.get() }; let bytes = self.bytes[current]; dest.copy_from_slice(bytes); // Remember that we returned this slice and prepare to return // the next one, if any. unsafe { *self.current.get() += 1 }; Ok(()) } } impl Drop for FixedSliceSequenceRandom<'_> { fn drop(&mut self) { // Ensure that `fill()` was called exactly the right number of // times. assert_eq!(unsafe { *self.current.get() }, self.bytes.len()); } } } #[cfg(test)] mod tests { use crate::{error, test}; #[test] fn one_ok() { test::run(test_file!("test_1_tests.txt"), |_, test_case| { let _ = test_case.consume_string("Key"); Ok(()) }); } #[test] #[should_panic(expected = "Test failed.")] fn one_err() { test::run(test_file!("test_1_tests.txt"), |_, test_case| { let _ = test_case.consume_string("Key"); Err(error::Unspecified) }); } #[test] #[should_panic(expected = "Oh noes!")] fn one_panics() { test::run(test_file!("test_1_tests.txt"), |_, test_case| { let _ = test_case.consume_string("Key"); panic!("Oh noes!"); }); } #[test] #[should_panic(expected = "Test failed.")] fn first_err() { err_one(0) } #[test] #[should_panic(expected = "Test failed.")] fn middle_err() { err_one(1) } #[test] #[should_panic(expected = "Test failed.")] fn last_err() { err_one(2) } fn err_one(test_to_fail: usize) { let mut n = 0; test::run(test_file!("test_3_tests.txt"), |_, test_case| { let _ = test_case.consume_string("Key"); let result = if n != test_to_fail { Ok(()) } else { Err(error::Unspecified) }; n += 1; result }); } #[test] #[should_panic(expected = "Oh Noes!")] fn first_panic() { panic_one(0) } #[test] #[should_panic(expected = "Oh Noes!")] fn middle_panic() { panic_one(1) } #[test] #[should_panic(expected = "Oh Noes!")] fn last_panic() { panic_one(2) } fn panic_one(test_to_fail: usize) { let mut n = 0; test::run(test_file!("test_3_tests.txt"), |_, test_case| { let _ = test_case.consume_string("Key"); if n == test_to_fail { panic!("Oh Noes!"); }; n += 1; Ok(()) }); } #[test] #[should_panic(expected = "Syntax error: Expected Key = Value.")] fn syntax_error() { test::run(test_file!("test_1_syntax_error_tests.txt"), |_, _| Ok(())); } }