// This file is part of Moonfire NVR, a security camera network video recorder. // Copyright (C) 2016 The Moonfire NVR Authors // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // In addition, as a special exception, the copyright holders give // permission to link the code of portions of this program with the // OpenSSL library under certain conditions as described in each // individual source file, and distribute linked combinations including // the two. // // You must obey the GNU General Public License in all respects for all // of the code used other than OpenSSL. If you modify file(s) with this // exception, you may extend this exception to your version of the // file(s), but you are not obligated to do so. If you do not wish to do // so, delete this exception statement from your version. If you delete // this exception statement from all source files in the program, then // also delete it here. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . //! Binary encoding/decoding. /// Zigzag-encodes a signed integer, as in [protocol buffer /// encoding](https://developers.google.com/protocol-buffers/docs/encoding#types). Uses the low bit /// to indicate signedness (1 = negative, 0 = non-negative). #[inline(always)] pub fn zigzag32(i: i32) -> u32 { ((i << 1) as u32) ^ ((i >> 31) as u32) } /// Zigzag-decodes to a signed integer. /// See `zigzag`. #[inline(always)] pub fn unzigzag32(i: u32) -> i32 { ((i >> 1) as i32) ^ -((i & 1) as i32) } #[inline(always)] pub fn decode_varint32(data: &[u8], i: usize) -> Result<(u32, usize), ()> { // Unroll a few likely possibilities before going into the robust out-of-line loop. // This aids branch prediction. if data.len() > i && (data[i] & 0x80) == 0 { return Ok((data[i] as u32, i+1)) } else if data.len() > i + 1 && (data[i+1] & 0x80) == 0 { return Ok((( (data[i] & 0x7f) as u32) | (( data[i+1] as u32) << 7), i+2)) } else if data.len() > i + 2 && (data[i+2] & 0x80) == 0 { return Ok((( (data[i] & 0x7f) as u32) | (((data[i+1] & 0x7f) as u32) << 7) | (( data[i+2] as u32) << 14), i+3)) } decode_varint32_slow(data, i) } #[cold] fn decode_varint32_slow(data: &[u8], mut i: usize) -> Result<(u32, usize), ()> { let l = data.len(); let mut out = 0; let mut shift = 0; loop { if i == l { return Err(()) } let b = data[i]; if shift == 28 && (b & 0xf0) != 0 { return Err(()) } out |= ((b & 0x7f) as u32) << shift; shift += 7; i += 1; if (b & 0x80) == 0 { break; } } Ok((out, i)) } pub fn append_varint32(i: u32, data: &mut Vec) { if i < 1u32 << 7 { data.push(i as u8); } else if i < 1u32 << 14 { data.extend_from_slice(&[(( i & 0x7F) | 0x80) as u8, (i >> 7) as u8]); } else if i < 1u32 << 21 { data.extend_from_slice(&[(( i & 0x7F) | 0x80) as u8, (((i >> 7) & 0x7F) | 0x80) as u8, (i >> 14) as u8]); } else if i < 1u32 << 28 { data.extend_from_slice(&[(( i & 0x7F) | 0x80) as u8, (((i >> 7) & 0x7F) | 0x80) as u8, (((i >> 14) & 0x7F) | 0x80) as u8, (i >> 21) as u8]); } else { data.extend_from_slice(&[(( i & 0x7F) | 0x80) as u8, (((i >> 7) & 0x7F) | 0x80) as u8, (((i >> 14) & 0x7F) | 0x80) as u8, (((i >> 21) & 0x7F) | 0x80) as u8, (i >> 28) as u8]); } } #[cfg(test)] mod tests { use super::*; #[test] fn test_zigzag() { struct Test { decoded: i32, encoded: u32, } let tests = [ Test{decoded: 0, encoded: 0}, Test{decoded: -1, encoded: 1}, Test{decoded: 1, encoded: 2}, Test{decoded: -2, encoded: 3}, Test{decoded: 2147483647, encoded: 4294967294}, Test{decoded: -2147483648, encoded: 4294967295}, ]; for test in &tests { assert_eq!(test.encoded, zigzag32(test.decoded)); assert_eq!(test.decoded, unzigzag32(test.encoded)); } } #[test] fn test_correct_varints() { struct Test { decoded: u32, encoded: &'static [u8], } let tests = [ Test{decoded: 1, encoded: b"\x01"}, Test{decoded: 257, encoded: b"\x81\x02"}, Test{decoded: 49409, encoded: b"\x81\x82\x03"}, Test{decoded: 8438017, encoded: b"\x81\x82\x83\x04"}, Test{decoded: 1350615297, encoded: b"\x81\x82\x83\x84\x05"}, ]; for test in &tests { // Test encoding to an empty buffer. let mut out = Vec::new(); append_varint32(test.decoded, &mut out); assert_eq!(&out[..], test.encoded); // ...and to a non-empty buffer. let mut buf = Vec::new(); out.clear(); out.push(b'x'); buf.push(b'x'); buf.extend_from_slice(test.encoded); append_varint32(test.decoded, &mut out); assert_eq!(out, buf); // Test decoding from the beginning of the string. assert_eq!((test.decoded, test.encoded.len()), decode_varint32(test.encoded, 0).unwrap()); // ...and from the middle of a buffer. buf.push(b'x'); assert_eq!((test.decoded, test.encoded.len() + 1), decode_varint32(&buf, 1).unwrap()); } } #[test] fn test_bad_varints() { let tests: &[&[u8]] = &[ // buffer underruns b"", b"\x80", b"\x80\x80", b"\x80\x80\x80", b"\x80\x80\x80\x80", // int32 overflows b"\x80\x80\x80\x80\x80", b"\x80\x80\x80\x80\x80\x00", ]; for (i, encoded) in tests.iter().enumerate() { assert!(decode_varint32(encoded, 0).is_err(), "while on test {}", i); } } }