// Copyright 2012 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. /*! * An implementation of the SHA-1 cryptographic hash. * * First create a `sha1` object using the `sha1` constructor, then * feed it input using the `input` or `input_str` methods, which may be * called any number of times. * * After the entire input has been fed to the hash read the result using * the `result` or `result_str` methods. * * The `sha1` object may be reused to create multiple hashes by calling * the `reset` method. */ use cryptoutil::{write_u32_be, read_u32v_be, add_bytes_to_bits, FixedBuffer, FixedBuffer64, StandardPadding}; use digest::Digest; /* * A SHA-1 implementation derived from Paul E. Jones's reference * implementation, which is written for clarity, not speed. At some * point this will want to be rewritten. */ // Some unexported constants static DIGEST_BUF_LEN: uint = 5u; static WORK_BUF_LEN: uint = 80u; static K0: u32 = 0x5A827999u32; static K1: u32 = 0x6ED9EBA1u32; static K2: u32 = 0x8F1BBCDCu32; static K3: u32 = 0xCA62C1D6u32; /// Structure representing the state of a Sha1 computation pub struct Sha1 { priv h: [u32, ..DIGEST_BUF_LEN], priv length_bits: u64, priv buffer: FixedBuffer64, priv computed: bool, } fn add_input(st: &mut Sha1, msg: &[u8]) { assert!((!st.computed)); // Assumes that msg.len() can be converted to u64 without overflow st.length_bits = add_bytes_to_bits(st.length_bits, msg.len() as u64); st.buffer.input(msg, |d: &[u8]| { process_msg_block(d, &mut st.h); }); } fn process_msg_block(data: &[u8], h: &mut [u32, ..DIGEST_BUF_LEN]) { let mut t: int; // Loop counter let mut w = [0u32, ..WORK_BUF_LEN]; // Initialize the first 16 words of the vector w read_u32v_be(w.mut_slice(0, 16), data); // Initialize the rest of vector w t = 16; while t < 80 { let val = w[t - 3] ^ w[t - 8] ^ w[t - 14] ^ w[t - 16]; w[t] = circular_shift(1, val); t += 1; } let mut a = h[0]; let mut b = h[1]; let mut c = h[2]; let mut d = h[3]; let mut e = h[4]; let mut temp: u32; t = 0; while t < 20 { temp = circular_shift(5, a) + (b & c | !b & d) + e + w[t] + K0; e = d; d = c; c = circular_shift(30, b); b = a; a = temp; t += 1; } while t < 40 { temp = circular_shift(5, a) + (b ^ c ^ d) + e + w[t] + K1; e = d; d = c; c = circular_shift(30, b); b = a; a = temp; t += 1; } while t < 60 { temp = circular_shift(5, a) + (b & c | b & d | c & d) + e + w[t] + K2; e = d; d = c; c = circular_shift(30, b); b = a; a = temp; t += 1; } while t < 80 { temp = circular_shift(5, a) + (b ^ c ^ d) + e + w[t] + K3; e = d; d = c; c = circular_shift(30, b); b = a; a = temp; t += 1; } h[0] += a; h[1] += b; h[2] += c; h[3] += d; h[4] += e; } fn circular_shift(bits: u32, word: u32) -> u32 { return word << bits | word >> 32u32 - bits; } fn mk_result(st: &mut Sha1, rs: &mut [u8]) { if !st.computed { st.buffer.standard_padding(8, |d: &[u8]| { process_msg_block(d, &mut st.h) }); write_u32_be(st.buffer.next(4), (st.length_bits >> 32) as u32 ); write_u32_be(st.buffer.next(4), st.length_bits as u32); process_msg_block(st.buffer.full_buffer(), &mut st.h); st.computed = true; } write_u32_be(rs.mut_slice(0, 4), st.h[0]); write_u32_be(rs.mut_slice(4, 8), st.h[1]); write_u32_be(rs.mut_slice(8, 12), st.h[2]); write_u32_be(rs.mut_slice(12, 16), st.h[3]); write_u32_be(rs.mut_slice(16, 20), st.h[4]); } impl Sha1 { /// Construct a `sha` object pub fn new() -> Sha1 { let mut st = Sha1 { h: [0u32, ..DIGEST_BUF_LEN], length_bits: 0u64, buffer: FixedBuffer64::new(), computed: false, }; st.reset(); return st; } } impl Digest for Sha1 { fn reset(&mut self) { self.length_bits = 0; self.h[0] = 0x67452301u32; self.h[1] = 0xEFCDAB89u32; self.h[2] = 0x98BADCFEu32; self.h[3] = 0x10325476u32; self.h[4] = 0xC3D2E1F0u32; self.buffer.reset(); self.computed = false; } fn input(&mut self, msg: &[u8]) { add_input(self, msg); } fn result(&mut self, out: &mut [u8]) { return mk_result(self, out); } fn output_bits(&self) -> uint { 160 } } #[cfg(test)] mod tests { use cryptoutil::test::test_digest_1million_random; use digest::Digest; use sha1::Sha1; #[deriving(Clone)] struct Test { input: ~str, output: ~[u8], output_str: ~str, } #[test] fn test() { // Test messages from FIPS 180-1 let fips_180_1_tests = ~[ Test { input: ~"abc", output: ~[ 0xA9u8, 0x99u8, 0x3Eu8, 0x36u8, 0x47u8, 0x06u8, 0x81u8, 0x6Au8, 0xBAu8, 0x3Eu8, 0x25u8, 0x71u8, 0x78u8, 0x50u8, 0xC2u8, 0x6Cu8, 0x9Cu8, 0xD0u8, 0xD8u8, 0x9Du8, ], output_str: ~"a9993e364706816aba3e25717850c26c9cd0d89d" }, Test { input: ~"abcdbcdecdefdefgefghfghighij" + "hijkijkljklmklmnlmnomnopnopq", output: ~[ 0x84u8, 0x98u8, 0x3Eu8, 0x44u8, 0x1Cu8, 0x3Bu8, 0xD2u8, 0x6Eu8, 0xBAu8, 0xAEu8, 0x4Au8, 0xA1u8, 0xF9u8, 0x51u8, 0x29u8, 0xE5u8, 0xE5u8, 0x46u8, 0x70u8, 0xF1u8, ], output_str: ~"84983e441c3bd26ebaae4aa1f95129e5e54670f1" }, ]; // Examples from wikipedia let wikipedia_tests = ~[ Test { input: ~"The quick brown fox jumps over the lazy dog", output: ~[ 0x2fu8, 0xd4u8, 0xe1u8, 0xc6u8, 0x7au8, 0x2du8, 0x28u8, 0xfcu8, 0xedu8, 0x84u8, 0x9eu8, 0xe1u8, 0xbbu8, 0x76u8, 0xe7u8, 0x39u8, 0x1bu8, 0x93u8, 0xebu8, 0x12u8, ], output_str: ~"2fd4e1c67a2d28fced849ee1bb76e7391b93eb12", }, Test { input: ~"The quick brown fox jumps over the lazy cog", output: ~[ 0xdeu8, 0x9fu8, 0x2cu8, 0x7fu8, 0xd2u8, 0x5eu8, 0x1bu8, 0x3au8, 0xfau8, 0xd3u8, 0xe8u8, 0x5au8, 0x0bu8, 0xd1u8, 0x7du8, 0x9bu8, 0x10u8, 0x0du8, 0xb4u8, 0xb3u8, ], output_str: ~"de9f2c7fd25e1b3afad3e85a0bd17d9b100db4b3", }, ]; let tests = fips_180_1_tests + wikipedia_tests; // Test that it works when accepting the message all at once let mut out = [0u8, ..20]; let mut sh = ~Sha1::new(); for t in tests.iter() { (*sh).input_str(t.input); sh.result(out); assert!(t.output.as_slice() == out); let out_str = (*sh).result_str(); assert_eq!(out_str.len(), 40); assert!(out_str == t.output_str); sh.reset(); } // Test that it works when accepting the message in pieces for t in tests.iter() { let len = t.input.len(); let mut left = len; while left > 0u { let take = (left + 1u) / 2u; (*sh).input_str(t.input.slice(len - left, take + len - left)); left = left - take; } sh.result(out); assert!(t.output.as_slice() == out); let out_str = (*sh).result_str(); assert_eq!(out_str.len(), 40); assert!(out_str == t.output_str); sh.reset(); } } #[test] fn test_1million_random_sha1() { let mut sh = Sha1::new(); test_digest_1million_random( &mut sh, 64, "34aa973cd4c4daa4f61eeb2bdbad27316534016f"); } } #[cfg(test)] mod bench { use sha1::Sha1; use test::BenchHarness; #[bench] pub fn sha1_10(bh: & mut BenchHarness) { let mut sh = Sha1::new(); let bytes = [1u8, ..10]; do bh.iter { sh.input(bytes); } bh.bytes = bytes.len() as u64; } #[bench] pub fn sha1_1k(bh: & mut BenchHarness) { let mut sh = Sha1::new(); let bytes = [1u8, ..1024]; do bh.iter { sh.input(bytes); } bh.bytes = bytes.len() as u64; } #[bench] pub fn sha1_64k(bh: & mut BenchHarness) { let mut sh = Sha1::new(); let bytes = [1u8, ..65536]; do bh.iter { sh.input(bytes); } bh.bytes = bytes.len() as u64; } }