// Rust Bitcoin Library // Written in 2014 by // Andrew Poelstra // // To the extent possible under law, the author(s) have dedicated all // copyright and related and neighboring rights to this software to // the public domain worldwide. This software is distributed without // any warranty. // // You should have received a copy of the CC0 Public Domain Dedication // along with this software. // If not, see . // //! Consensus-encodable types //! //! This is basically a replacement of the `Encodable` trait which does //! normalization for endianness, etc., to ensure that the encoding //! matches for endianness, etc., to ensure that the encoding matches //! the network consensus encoding. //! //! Essentially, anything that must go on the -disk- or -network- must //! be encoded using the `Encodable` trait, since this data //! must be the same for all systems. Any data going to the -user-, e.g. //! over JSONRPC, should use the ordinary `Encodable` trait. (This //! should also be the same across systems, of course, but has some //! critical differences from the network format, e.g. scripts come //! with an opcode decode, hashes are big-endian, numbers are typically //! big-endian decimals, etc.) //! use std::collections::HashMap; use std::hash::Hash; use std::{mem, u32}; use std::error; use std::fmt; use std::io; use std::io::{Cursor, Read, Write}; use byteorder::{LittleEndian, WriteBytesExt, ReadBytesExt}; use hex::encode as hex_encode; use bitcoin_bech32; use bitcoin_hashes::{sha256d, Hash as HashTrait}; use secp256k1; use util::base58; /// Encoding error #[derive(Debug)] pub enum Error { /// And I/O error Io(io::Error), /// Base58 encoding error Base58(base58::Error), /// Bech32 encoding error Bech32(bitcoin_bech32::Error), /// Error from the `byteorder` crate ByteOrder(io::Error), /// secp-related error Secp256k1(secp256k1::Error), /// Network magic was not expected UnexpectedNetworkMagic { /// The expected network magic expected: u32, /// The unexpected network magic actual: u32, }, /// Tried to allocate an oversized vector OversizedVectorAllocation{ /// The capacity requested requested: usize, /// The maximum capacity max: usize, }, /// Checksum was invalid InvalidChecksum { /// The expected checksum expected: [u8; 4], /// The invalid checksum actual: [u8; 4], }, /// Network magic was unknown UnknownNetworkMagic(u32), /// Parsing error ParseFailed(&'static str), /// Unsupported witness version UnsupportedWitnessVersion(u8), /// Unsupported Segwit flag UnsupportedSegwitFlag(u8), /// Unrecognized network command UnrecognizedNetworkCommand(String), /// Unexpected hex digit UnexpectedHexDigit(char), } impl fmt::Display for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { Error::Io(ref e) => fmt::Display::fmt(e, f), Error::Base58(ref e) => fmt::Display::fmt(e, f), Error::Bech32(ref e) => fmt::Display::fmt(e, f), Error::ByteOrder(ref e) => fmt::Display::fmt(e, f), Error::Secp256k1(ref e) => fmt::Display::fmt(e, f), Error::UnexpectedNetworkMagic { expected: ref e, actual: ref a } => write!(f, "{}: expected {}, actual {}", error::Error::description(self), e, a), Error::OversizedVectorAllocation { requested: ref r, max: ref m } => write!(f, "{}: requested {}, maximum {}", error::Error::description(self), r, m), Error::InvalidChecksum { expected: ref e, actual: ref a } => write!(f, "{}: expected {}, actual {}", error::Error::description(self), hex_encode(e), hex_encode(a)), Error::UnknownNetworkMagic(ref m) => write!(f, "{}: {}", error::Error::description(self), m), Error::ParseFailed(ref e) => write!(f, "{}: {}", error::Error::description(self), e), Error::UnsupportedWitnessVersion(ref wver) => write!(f, "{}: {}", error::Error::description(self), wver), Error::UnsupportedSegwitFlag(ref swflag) => write!(f, "{}: {}", error::Error::description(self), swflag), Error::UnrecognizedNetworkCommand(ref nwcmd) => write!(f, "{}: {}", error::Error::description(self), nwcmd), Error::UnexpectedHexDigit(ref d) => write!(f, "{}: {}", error::Error::description(self), d), } } } impl error::Error for Error { fn cause(&self) -> Option<&error::Error> { match *self { Error::Io(ref e) => Some(e), Error::Base58(ref e) => Some(e), Error::Bech32(ref e) => Some(e), Error::ByteOrder(ref e) => Some(e), Error::Secp256k1(ref e) => Some(e), Error::UnexpectedNetworkMagic { .. } | Error::OversizedVectorAllocation { .. } | Error::InvalidChecksum { .. } | Error::UnknownNetworkMagic(..) | Error::ParseFailed(..) | Error::UnsupportedWitnessVersion(..) | Error::UnsupportedSegwitFlag(..) | Error::UnrecognizedNetworkCommand(..) | Error::UnexpectedHexDigit(..) => None, } } fn description(&self) -> &str { match *self { Error::Io(ref e) => e.description(), Error::Base58(ref e) => e.description(), Error::Bech32(ref e) => e.description(), Error::ByteOrder(ref e) => e.description(), Error::Secp256k1(ref e) => e.description(), Error::UnexpectedNetworkMagic { .. } => "unexpected network magic", Error::OversizedVectorAllocation { .. } => "allocation of oversized vector requested", Error::InvalidChecksum { .. } => "invalid checksum", Error::UnknownNetworkMagic(..) => "unknown network magic", Error::ParseFailed(..) => "parse failed", Error::UnsupportedWitnessVersion(..) => "unsupported witness version", Error::UnsupportedSegwitFlag(..) => "unsupported segwit version", Error::UnrecognizedNetworkCommand(..) => "unrecognized network command", Error::UnexpectedHexDigit(..) => "unexpected hex digit", } } } #[doc(hidden)] impl From for Error { fn from(e: base58::Error) -> Error { Error::Base58(e) } } #[doc(hidden)] impl From for Error { fn from(e: bitcoin_bech32::Error) -> Error { Error::Bech32(e) } } #[doc(hidden)] impl From for Error { fn from(e: secp256k1::Error) -> Error { Error::Secp256k1(e) } } #[doc(hidden)] impl From for Error { fn from(error: io::Error) -> Self { Error::Io(error) } } /// Encode an object into a vector pub fn serialize(data: &T) -> Vec where T: Encodable>>, { let mut encoder = Cursor::new(vec![]); data.consensus_encode(&mut encoder).unwrap(); encoder.into_inner() } /// Encode an object into a hex-encoded string pub fn serialize_hex(data: &T) -> String where T: Encodable>> { hex_encode(serialize(data)) } /// Deserialize an object from a vector, will error if said deserialization /// doesn't consume the entire vector. pub fn deserialize<'a, T>(data: &'a [u8]) -> Result where T: Decodable> { let (rv, consumed) = deserialize_partial(data)?; // Fail if data are not consumed entirely. if consumed == data.len() { Ok(rv) } else { Err(Error::ParseFailed("data not consumed entirely when explicitly deserializing")) } } /// Deserialize an object from a vector, but will not report an error if said deserialization /// doesn't consume the entire vector. pub fn deserialize_partial<'a, T>(data: &'a [u8]) -> Result<(T, usize), Error> where T: Decodable> { let mut decoder = Cursor::new(data); let rv = Decodable::consensus_decode(&mut decoder)?; let consumed = decoder.position() as usize; Ok((rv, consumed)) } /// A simple Encoder trait pub trait Encoder { /// Output a 64-bit uint fn emit_u64(&mut self, v: u64) -> Result<(), Error>; /// Output a 32-bit uint fn emit_u32(&mut self, v: u32) -> Result<(), Error>; /// Output a 16-bit uint fn emit_u16(&mut self, v: u16) -> Result<(), Error>; /// Output a 8-bit uint fn emit_u8(&mut self, v: u8) -> Result<(), Error>; /// Output a 64-bit int fn emit_i64(&mut self, v: i64) -> Result<(), Error>; /// Output a 32-bit int fn emit_i32(&mut self, v: i32) -> Result<(), Error>; /// Output a 16-bit int fn emit_i16(&mut self, v: i16) -> Result<(), Error>; /// Output a 8-bit int fn emit_i8(&mut self, v: i8) -> Result<(), Error>; /// Output a boolean fn emit_bool(&mut self, v: bool) -> Result<(), Error>; } /// A simple Decoder trait pub trait Decoder { /// Read a 64-bit uint fn read_u64(&mut self) -> Result; /// Read a 32-bit uint fn read_u32(&mut self) -> Result; /// Read a 16-bit uint fn read_u16(&mut self) -> Result; /// Read a 8-bit uint fn read_u8(&mut self) -> Result; /// Read a 64-bit int fn read_i64(&mut self) -> Result; /// Read a 32-bit int fn read_i32(&mut self) -> Result; /// Read a 16-bit int fn read_i16(&mut self) -> Result; /// Read a 8-bit int fn read_i8(&mut self) -> Result; /// Read a boolean fn read_bool(&mut self) -> Result; } macro_rules! encoder_fn { ($name:ident, $val_type:ty, $writefn:ident) => { #[inline] fn $name(&mut self, v: $val_type) -> Result<(), Error> { WriteBytesExt::$writefn::(self, v).map_err(Error::Io) } } } macro_rules! decoder_fn { ($name:ident, $val_type:ty, $readfn:ident) => { #[inline] fn $name(&mut self) -> Result<$val_type, Error> { ReadBytesExt::$readfn::(self).map_err(Error::Io) } } } impl Encoder for W { encoder_fn!(emit_u64, u64, write_u64); encoder_fn!(emit_u32, u32, write_u32); encoder_fn!(emit_u16, u16, write_u16); encoder_fn!(emit_i64, i64, write_i64); encoder_fn!(emit_i32, i32, write_i32); encoder_fn!(emit_i16, i16, write_i16); #[inline] fn emit_i8(&mut self, v: i8) -> Result<(), Error> { self.write_i8(v).map_err(Error::Io) } #[inline] fn emit_u8(&mut self, v: u8) -> Result<(), Error> { self.write_u8(v).map_err(Error::Io) } #[inline] fn emit_bool(&mut self, v: bool) -> Result<(), Error> { self.write_i8(if v {1} else {0}).map_err(Error::Io) } } impl Decoder for R { decoder_fn!(read_u64, u64, read_u64); decoder_fn!(read_u32, u32, read_u32); decoder_fn!(read_u16, u16, read_u16); decoder_fn!(read_i64, i64, read_i64); decoder_fn!(read_i32, i32, read_i32); decoder_fn!(read_i16, i16, read_i16); #[inline] fn read_u8(&mut self) -> Result { ReadBytesExt::read_u8(self).map_err(Error::Io) } #[inline] fn read_i8(&mut self) -> Result { ReadBytesExt::read_i8(self).map_err(Error::Io) } #[inline] fn read_bool(&mut self) -> Result { Decoder::read_i8(self).map(|bit| bit != 0) } } /// Maximum size, in bytes, of a vector we are allowed to decode pub const MAX_VEC_SIZE: usize = 32 * 1024 * 1024; /// Data which can be encoded in a consensus-consistent way pub trait Encodable { /// Encode an object with a well-defined format, should only ever error if /// the underlying Encoder errors. fn consensus_encode(&self, e: &mut S) -> Result<(), self::Error>; } /// Data which can be encoded in a consensus-consistent way pub trait Decodable: Sized { /// Decode an object with a well-defined format fn consensus_decode(d: &mut D) -> Result; } /// A variable-length unsigned integer #[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Debug)] pub struct VarInt(pub u64); /// Data which must be preceded by a 4-byte checksum #[derive(PartialEq, Eq, Clone, Debug)] pub struct CheckedData(pub Vec); // Primitive types macro_rules! impl_int_encodable{ ($ty:ident, $meth_dec:ident, $meth_enc:ident) => ( impl Decodable for $ty { #[inline] fn consensus_decode(d: &mut D) -> Result<$ty, self::Error> { d.$meth_dec().map($ty::from_le) } } impl Encodable for $ty { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { s.$meth_enc(self.to_le()) } } ) } impl_int_encodable!(u8, read_u8, emit_u8); impl_int_encodable!(u16, read_u16, emit_u16); impl_int_encodable!(u32, read_u32, emit_u32); impl_int_encodable!(u64, read_u64, emit_u64); impl_int_encodable!(i8, read_i8, emit_i8); impl_int_encodable!(i16, read_i16, emit_i16); impl_int_encodable!(i32, read_i32, emit_i32); impl_int_encodable!(i64, read_i64, emit_i64); impl VarInt { /// Gets the length of this VarInt when encoded. /// Returns 1 for 0...0xFC, 3 for 0xFD...(2^16-1), 5 for 0x10000...(2^32-1), /// and 9 otherwise. #[inline] pub fn encoded_length(&self) -> u64 { match self.0 { 0...0xFC => { 1 } 0xFD...0xFFFF => { 3 } 0x10000...0xFFFFFFFF => { 5 } _ => { 9 } } } } impl Encodable for VarInt { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { match self.0 { 0...0xFC => { (self.0 as u8).consensus_encode(s) } 0xFD...0xFFFF => { s.emit_u8(0xFD)?; (self.0 as u16).consensus_encode(s) } 0x10000...0xFFFFFFFF => { s.emit_u8(0xFE)?; (self.0 as u32).consensus_encode(s) } _ => { s.emit_u8(0xFF)?; (self.0 as u64).consensus_encode(s) } } } } impl Decodable for VarInt { #[inline] fn consensus_decode(d: &mut D) -> Result { let n = d.read_u8()?; match n { 0xFF => { let x = d.read_u64()?; if x < 0x100000000 { Err(self::Error::ParseFailed("non-minimal varint")) } else { Ok(VarInt(x)) } } 0xFE => { let x = d.read_u32()?; if x < 0x10000 { Err(self::Error::ParseFailed("non-minimal varint")) } else { Ok(VarInt(x as u64)) } } 0xFD => { let x = d.read_u16()?; if x < 0xFD { Err(self::Error::ParseFailed("non-minimal varint")) } else { Ok(VarInt(x as u64)) } } n => Ok(VarInt(n as u64)) } } } // Booleans impl Encodable for bool { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { s.emit_u8(if *self {1} else {0}) } } impl Decodable for bool { #[inline] fn consensus_decode(d: &mut D) -> Result { d.read_u8().map(|n| n != 0) } } // Strings impl Encodable for String { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { self.as_bytes().consensus_encode(s) } } impl Decodable for String { #[inline] fn consensus_decode(d: &mut D) -> Result { String::from_utf8(Decodable::consensus_decode(d)?) .map_err(|_| self::Error::ParseFailed("String was not valid UTF8")) } } // Arrays macro_rules! impl_array { ( $size:expr ) => ( impl> Encodable for [T; $size] { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { for i in self.iter() { i.consensus_encode(s)?; } Ok(()) } } impl + Copy> Decodable for [T; $size] { #[inline] fn consensus_decode(d: &mut D) -> Result<[T; $size], self::Error> { // Set everything to the first decode let mut ret = [Decodable::consensus_decode(d)?; $size]; // Set the rest for item in ret.iter_mut().take($size).skip(1) { *item = Decodable::consensus_decode(d)?; } Ok(ret) } } ); } impl_array!(2); impl_array!(4); impl_array!(8); impl_array!(12); impl_array!(16); impl_array!(32); impl> Encodable for [T] { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { VarInt(self.len() as u64).consensus_encode(s)?; for c in self.iter() { c.consensus_encode(s)?; } Ok(()) } } // Cannot decode a slice // Vectors impl> Encodable for Vec { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { (&self[..]).consensus_encode(s) } } impl> Decodable for Vec { #[inline] fn consensus_decode(d: &mut D) -> Result, self::Error> { let len = VarInt::consensus_decode(d)?.0; let byte_size = (len as usize) .checked_mul(mem::size_of::()) .ok_or(self::Error::ParseFailed("Invalid length"))?; if byte_size > MAX_VEC_SIZE { return Err(self::Error::OversizedVectorAllocation { requested: byte_size, max: MAX_VEC_SIZE }) } let mut ret = Vec::with_capacity(len as usize); for _ in 0..len { ret.push(Decodable::consensus_decode(d)?); } Ok(ret) } } impl> Encodable for Box<[T]> { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { (&self[..]).consensus_encode(s) } } impl> Decodable for Box<[T]> { #[inline] fn consensus_decode(d: &mut D) -> Result, self::Error> { let len = VarInt::consensus_decode(d)?.0; let len = len as usize; if len > MAX_VEC_SIZE { return Err(self::Error::OversizedVectorAllocation { requested: len, max: MAX_VEC_SIZE }) } let mut ret = Vec::with_capacity(len); for _ in 0..len { ret.push(Decodable::consensus_decode(d)?); } Ok(ret.into_boxed_slice()) } } /// Do a double-SHA256 on some data and return the first 4 bytes fn sha2_checksum(data: &[u8]) -> [u8; 4] { let checksum = ::hash(data); [checksum[0], checksum[1], checksum[2], checksum[3]] } // Checked data impl Encodable for CheckedData { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { (self.0.len() as u32).consensus_encode(s)?; sha2_checksum(&self.0).consensus_encode(s)?; // We can't just pass to the slice encoder since it'll insert a length for ch in &self.0 { ch.consensus_encode(s)?; } Ok(()) } } impl Decodable for CheckedData { #[inline] fn consensus_decode(d: &mut D) -> Result { let len: u32 = Decodable::consensus_decode(d)?; let checksum: [u8; 4] = Decodable::consensus_decode(d)?; let mut ret = Vec::with_capacity(len as usize); for _ in 0..len { ret.push(Decodable::consensus_decode(d)?); } let expected_checksum = sha2_checksum(&ret); if expected_checksum != checksum { Err(self::Error::InvalidChecksum { expected: expected_checksum, actual: checksum, }) } else { Ok(CheckedData(ret)) } } } // Tuples macro_rules! tuple_encode { ($($x:ident),*) => ( impl ),*> Encodable for ($($x),*) { #[inline] #[allow(non_snake_case)] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { let &($(ref $x),*) = self; $( $x.consensus_encode(s)?; )* Ok(()) } } impl),*> Decodable for ($($x),*) { #[inline] #[allow(non_snake_case)] fn consensus_decode(d: &mut D) -> Result<($($x),*), self::Error> { Ok(($({let $x = Decodable::consensus_decode(d)?; $x }),*)) } } ); } tuple_encode!(T0, T1); tuple_encode!(T0, T1, T2, T3); tuple_encode!(T0, T1, T2, T3, T4, T5); tuple_encode!(T0, T1, T2, T3, T4, T5, T6, T7); // References impl> Encodable for Box { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { (**self).consensus_encode(s) } } impl> Decodable for Box { #[inline] fn consensus_decode(d: &mut D) -> Result, self::Error> { Decodable::consensus_decode(d).map(Box::new) } } // HashMap impl Encodable for HashMap where S: Encoder, K: Encodable + Eq + Hash, V: Encodable { #[inline] fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { VarInt(self.len() as u64).consensus_encode(s)?; for (key, value) in self.iter() { key.consensus_encode(s)?; value.consensus_encode(s)?; } Ok(()) } } impl Decodable for HashMap where D: Decoder, K: Decodable + Eq + Hash, V: Decodable { #[inline] fn consensus_decode(d: &mut D) -> Result, self::Error> { let len = VarInt::consensus_decode(d)?.0; let mut ret = HashMap::with_capacity(len as usize); for _ in 0..len { ret.insert(Decodable::consensus_decode(d)?, Decodable::consensus_decode(d)?); } Ok(ret) } } impl Encodable for sha256d::Hash { fn consensus_encode(&self, s: &mut S) -> Result<(), self::Error> { self.into_inner().consensus_encode(s) } } impl Decodable for sha256d::Hash { fn consensus_decode(d: &mut D) -> Result { let inner: [u8; 32] = Decodable::consensus_decode(d)?; Ok(sha256d::Hash::from_slice(&inner).unwrap()) } } // Tests #[cfg(test)] mod tests { use super::{CheckedData, VarInt}; use super::{deserialize, serialize, Error}; #[test] fn serialize_int_test() { // bool assert_eq!(serialize(&false), vec![0u8]); assert_eq!(serialize(&true), vec![1u8]); // u8 assert_eq!(serialize(&1u8), vec![1u8]); assert_eq!(serialize(&0u8), vec![0u8]); assert_eq!(serialize(&255u8), vec![255u8]); // u16 assert_eq!(serialize(&1u16), vec![1u8, 0]); assert_eq!(serialize(&256u16), vec![0u8, 1]); assert_eq!(serialize(&5000u16), vec![136u8, 19]); // u32 assert_eq!(serialize(&1u32), vec![1u8, 0, 0, 0]); assert_eq!(serialize(&256u32), vec![0u8, 1, 0, 0]); assert_eq!(serialize(&5000u32), vec![136u8, 19, 0, 0]); assert_eq!(serialize(&500000u32), vec![32u8, 161, 7, 0]); assert_eq!(serialize(&168430090u32), vec![10u8, 10, 10, 10]); // TODO: test negative numbers assert_eq!(serialize(&1i32), vec![1u8, 0, 0, 0]); assert_eq!(serialize(&256i32), vec![0u8, 1, 0, 0]); assert_eq!(serialize(&5000i32), vec![136u8, 19, 0, 0]); assert_eq!(serialize(&500000i32), vec![32u8, 161, 7, 0]); assert_eq!(serialize(&168430090i32), vec![10u8, 10, 10, 10]); // u64 assert_eq!(serialize(&1u64), vec![1u8, 0, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&256u64), vec![0u8, 1, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&5000u64), vec![136u8, 19, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&500000u64), vec![32u8, 161, 7, 0, 0, 0, 0, 0]); assert_eq!(serialize(&723401728380766730u64), vec![10u8, 10, 10, 10, 10, 10, 10, 10]); // TODO: test negative numbers assert_eq!(serialize(&1i64), vec![1u8, 0, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&256i64), vec![0u8, 1, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&5000i64), vec![136u8, 19, 0, 0, 0, 0, 0, 0]); assert_eq!(serialize(&500000i64), vec![32u8, 161, 7, 0, 0, 0, 0, 0]); assert_eq!(serialize(&723401728380766730i64), vec![10u8, 10, 10, 10, 10, 10, 10, 10]); } #[test] fn serialize_varint_test() { assert_eq!(serialize(&VarInt(10)), vec![10u8]); assert_eq!(serialize(&VarInt(0xFC)), vec![0xFCu8]); assert_eq!(serialize(&VarInt(0xFD)), vec![0xFDu8, 0xFD, 0]); assert_eq!(serialize(&VarInt(0xFFF)), vec![0xFDu8, 0xFF, 0xF]); assert_eq!(serialize(&VarInt(0xF0F0F0F)), vec![0xFEu8, 0xF, 0xF, 0xF, 0xF]); assert_eq!(serialize(&VarInt(0xF0F0F0F0F0E0)), vec![0xFFu8, 0xE0, 0xF0, 0xF0, 0xF0, 0xF0, 0xF0, 0, 0]); } #[test] fn deserialize_nonminimal_vec() { match deserialize::>(&[0xfd, 0x00, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } match deserialize::>(&[0xfd, 0xfc, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } match deserialize::>(&[0xfe, 0xff, 0x00, 0x00, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } match deserialize::>(&[0xfe, 0xff, 0xff, 0x00, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } match deserialize::>(&[0xff, 0xff, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } match deserialize::>(&[0xff, 0xff, 0xff, 0xff, 0x00, 0x00, 0x00, 0x00, 0x00]) { Err(Error::ParseFailed("non-minimal varint")) => {}, x => panic!(x) } let mut vec_256 = vec![0; 259]; vec_256[0] = 0xfd; vec_256[1] = 0x00; vec_256[2] = 0x01; assert!(deserialize::>(&vec_256).is_ok()); let mut vec_253 = vec![0; 256]; vec_253[0] = 0xfd; vec_253[1] = 0xfd; vec_253[2] = 0x00; assert!(deserialize::>(&vec_253).is_ok()); } #[test] fn serialize_checkeddata_test() { let cd = CheckedData(vec![1u8, 2, 3, 4, 5]); assert_eq!(serialize(&cd), vec![5, 0, 0, 0, 162, 107, 175, 90, 1, 2, 3, 4, 5]); } #[test] fn serialize_vector_test() { assert_eq!(serialize(&vec![1u8, 2, 3]), vec![3u8, 1, 2, 3]); assert_eq!(serialize(&[1u8, 2, 3][..]), vec![3u8, 1, 2, 3]); // TODO: test vectors of more interesting objects } #[test] fn serialize_strbuf_test() { assert_eq!(serialize(&"Andrew".to_string()), vec![6u8, 0x41, 0x6e, 0x64, 0x72, 0x65, 0x77]); } #[test] fn serialize_box_test() { assert_eq!(serialize(&Box::new(1u8)), vec![1u8]); assert_eq!(serialize(&Box::new(1u16)), vec![1u8, 0]); assert_eq!(serialize(&Box::new(1u64)), vec![1u8, 0, 0, 0, 0, 0, 0, 0]); } #[test] fn deserialize_int_test() { // bool assert!((deserialize(&[58u8, 0]) as Result).is_err()); assert_eq!(deserialize(&[58u8]).ok(), Some(true)); assert_eq!(deserialize(&[1u8]).ok(), Some(true)); assert_eq!(deserialize(&[0u8]).ok(), Some(false)); assert!((deserialize(&[0u8, 1]) as Result).is_err()); // u8 assert_eq!(deserialize(&[58u8]).ok(), Some(58u8)); // u16 assert_eq!(deserialize(&[0x01u8, 0x02]).ok(), Some(0x0201u16)); assert_eq!(deserialize(&[0xABu8, 0xCD]).ok(), Some(0xCDABu16)); assert_eq!(deserialize(&[0xA0u8, 0x0D]).ok(), Some(0xDA0u16)); let failure16: Result = deserialize(&[1u8]); assert!(failure16.is_err()); // u32 assert_eq!(deserialize(&[0xABu8, 0xCD, 0, 0]).ok(), Some(0xCDABu32)); assert_eq!(deserialize(&[0xA0u8, 0x0D, 0xAB, 0xCD]).ok(), Some(0xCDAB0DA0u32)); let failure32: Result = deserialize(&[1u8, 2, 3]); assert!(failure32.is_err()); // TODO: test negative numbers assert_eq!(deserialize(&[0xABu8, 0xCD, 0, 0]).ok(), Some(0xCDABi32)); assert_eq!(deserialize(&[0xA0u8, 0x0D, 0xAB, 0x2D]).ok(), Some(0x2DAB0DA0i32)); let failurei32: Result = deserialize(&[1u8, 2, 3]); assert!(failurei32.is_err()); // u64 assert_eq!(deserialize(&[0xABu8, 0xCD, 0, 0, 0, 0, 0, 0]).ok(), Some(0xCDABu64)); assert_eq!(deserialize(&[0xA0u8, 0x0D, 0xAB, 0xCD, 0x99, 0, 0, 0x99]).ok(), Some(0x99000099CDAB0DA0u64)); let failure64: Result = deserialize(&[1u8, 2, 3, 4, 5, 6, 7]); assert!(failure64.is_err()); // TODO: test negative numbers assert_eq!(deserialize(&[0xABu8, 0xCD, 0, 0, 0, 0, 0, 0]).ok(), Some(0xCDABi64)); assert_eq!(deserialize(&[0xA0u8, 0x0D, 0xAB, 0xCD, 0x99, 0, 0, 0x99]).ok(), Some(-0x66ffff663254f260i64)); let failurei64: Result = deserialize(&[1u8, 2, 3, 4, 5, 6, 7]); assert!(failurei64.is_err()); } #[test] fn deserialize_vec_test() { assert_eq!(deserialize(&[3u8, 2, 3, 4]).ok(), Some(vec![2u8, 3, 4])); assert!((deserialize(&[4u8, 2, 3, 4, 5, 6]) as Result, _>).is_err()); // found by cargo fuzz assert!(deserialize::>(&[0xff,0xff,0xff,0xff,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0x6b,0xa,0xa,0x3a]).is_err()); } #[test] fn deserialize_strbuf_test() { assert_eq!(deserialize(&[6u8, 0x41, 0x6e, 0x64, 0x72, 0x65, 0x77]).ok(), Some("Andrew".to_string())); } #[test] fn deserialize_checkeddata_test() { let cd: Result = deserialize(&[5u8, 0, 0, 0, 162, 107, 175, 90, 1, 2, 3, 4, 5]); assert_eq!(cd.ok(), Some(CheckedData(vec![1u8, 2, 3, 4, 5]))); } #[test] fn deserialize_box_test() { let zero: Result, _> = deserialize(&[0u8]); let one: Result, _> = deserialize(&[1u8]); assert_eq!(zero.ok(), Some(Box::new(0))); assert_eq!(one.ok(), Some(Box::new(1))); } }