// This file is Copyright its original authors, visible in version control
// history.
//
// This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
// or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
// You may not use this file except in accordance with one or both of these
// licenses.
macro_rules! encode_tlv {
($stream: expr, $type: expr, $field: expr, (default_value, $default: expr)) => {
encode_tlv!($stream, $type, $field, required)
};
($stream: expr, $type: expr, $field: expr, required) => {
BigSize($type).write($stream)?;
BigSize($field.serialized_length() as u64).write($stream)?;
$field.write($stream)?;
};
($stream: expr, $type: expr, $field: expr, vec_type) => {
encode_tlv!($stream, $type, ::util::ser::VecWriteWrapper(&$field), required);
};
($stream: expr, $optional_type: expr, $optional_field: expr, option) => {
if let Some(ref field) = $optional_field {
BigSize($optional_type).write($stream)?;
BigSize(field.serialized_length() as u64).write($stream)?;
field.write($stream)?;
}
};
}
macro_rules! encode_tlv_stream {
($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),* $(,)*}) => { {
#[allow(unused_imports)]
use {
ln::msgs::DecodeError,
util::ser,
util::ser::BigSize,
};
$(
encode_tlv!($stream, $type, $field, $fieldty);
)*
#[allow(unused_mut, unused_variables, unused_assignments)]
#[cfg(debug_assertions)]
{
let mut last_seen: Option<u64> = None;
$(
if let Some(t) = last_seen {
debug_assert!(t <= $type);
}
last_seen = Some($type);
)*
}
} }
}
macro_rules! get_varint_length_prefixed_tlv_length {
($len: expr, $type: expr, $field: expr, (default_value, $default: expr)) => {
get_varint_length_prefixed_tlv_length!($len, $type, $field, required)
};
($len: expr, $type: expr, $field: expr, required) => {
BigSize($type).write(&mut $len).expect("No in-memory data may fail to serialize");
let field_len = $field.serialized_length();
BigSize(field_len as u64).write(&mut $len).expect("No in-memory data may fail to serialize");
$len.0 += field_len;
};
($len: expr, $type: expr, $field: expr, vec_type) => {
get_varint_length_prefixed_tlv_length!($len, $type, ::util::ser::VecWriteWrapper(&$field), required);
};
($len: expr, $optional_type: expr, $optional_field: expr, option) => {
if let Some(ref field) = $optional_field {
BigSize($optional_type).write(&mut $len).expect("No in-memory data may fail to serialize");
let field_len = field.serialized_length();
BigSize(field_len as u64).write(&mut $len).expect("No in-memory data may fail to serialize");
$len.0 += field_len;
}
};
}
macro_rules! encode_varint_length_prefixed_tlv {
($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),*}) => { {
use util::ser::BigSize;
let len = {
#[allow(unused_mut)]
let mut len = ::util::ser::LengthCalculatingWriter(0);
$(
get_varint_length_prefixed_tlv_length!(len, $type, $field, $fieldty);
)*
len.0
};
BigSize(len as u64).write($stream)?;
encode_tlv_stream!($stream, { $(($type, $field, $fieldty)),* });
} }
}
macro_rules! check_tlv_order {
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (default_value, $default: expr)) => {{
#[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always true
let invalid_order = ($last_seen_type.is_none() || $last_seen_type.unwrap() < $type) && $typ.0 > $type;
if invalid_order {
$field = $default;
}
}};
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, required) => {{
#[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always true
let invalid_order = ($last_seen_type.is_none() || $last_seen_type.unwrap() < $type) && $typ.0 > $type;
if invalid_order {
return Err(DecodeError::InvalidValue);
}
}};
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, option) => {{
// no-op
}};
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, vec_type) => {{
// no-op
}};
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, ignorable) => {{
// no-op
}};
}
macro_rules! check_missing_tlv {
($last_seen_type: expr, $type: expr, $field: ident, (default_value, $default: expr)) => {{
#[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always true
let missing_req_type = $last_seen_type.is_none() || $last_seen_type.unwrap() < $type;
if missing_req_type {
$field = $default;
}
}};
($last_seen_type: expr, $type: expr, $field: ident, required) => {{
#[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always true
let missing_req_type = $last_seen_type.is_none() || $last_seen_type.unwrap() < $type;
if missing_req_type {
return Err(DecodeError::InvalidValue);
}
}};
($last_seen_type: expr, $type: expr, $field: ident, vec_type) => {{
// no-op
}};
($last_seen_type: expr, $type: expr, $field: ident, option) => {{
// no-op
}};
($last_seen_type: expr, $type: expr, $field: ident, ignorable) => {{
// no-op
}};
}
macro_rules! decode_tlv {
($reader: expr, $field: ident, (default_value, $default: expr)) => {{
decode_tlv!($reader, $field, required)
}};
($reader: expr, $field: ident, required) => {{
$field = ser::Readable::read(&mut $reader)?;
}};
($reader: expr, $field: ident, vec_type) => {{
$field = Some(ser::Readable::read(&mut $reader)?);
}};
($reader: expr, $field: ident, option) => {{
$field = Some(ser::Readable::read(&mut $reader)?);
}};
($reader: expr, $field: ident, ignorable) => {{
$field = ser::MaybeReadable::read(&mut $reader)?;
}};
}
macro_rules! decode_tlv_stream {
($stream: expr, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => { {
use ln::msgs::DecodeError;
let mut last_seen_type: Option<u64> = None;
let mut stream_ref = $stream;
'tlv_read: loop {
use util::ser;
// First decode the type of this TLV:
let typ: ser::BigSize = {
// We track whether any bytes were read during the consensus_decode call to
// determine whether we should break or return ShortRead if we get an
// UnexpectedEof. This should in every case be largely cosmetic, but its nice to
// pass the TLV test vectors exactly, which requre this distinction.
let mut tracking_reader = ser::ReadTrackingReader::new(&mut stream_ref);
match ser::Readable::read(&mut tracking_reader) {
Err(DecodeError::ShortRead) => {
if !tracking_reader.have_read {
break 'tlv_read;
} else {
return Err(DecodeError::ShortRead);
}
},
Err(e) => return Err(e),
Ok(t) => t,
}
};
// Types must be unique and monotonically increasing:
match last_seen_type {
Some(t) if typ.0 <= t => {
return Err(DecodeError::InvalidValue);
},
_ => {},
}
// As we read types, make sure we hit every required type:
$({
check_tlv_order!(last_seen_type, typ, $type, $field, $fieldty);
})*
last_seen_type = Some(typ.0);
// Finally, read the length and value itself:
let length: ser::BigSize = ser::Readable::read(&mut stream_ref)?;
let mut s = ser::FixedLengthReader::new(&mut stream_ref, length.0);
match typ.0 {
$($type => {
decode_tlv!(s, $field, $fieldty);
if s.bytes_remain() {
s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
return Err(DecodeError::InvalidValue);
}
},)*
x if x % 2 == 0 => {
return Err(DecodeError::UnknownRequiredFeature);
},
_ => {},
}
s.eat_remaining()?;
}
// Make sure we got to each required type after we've read every TLV:
$({
check_missing_tlv!(last_seen_type, $type, $field, $fieldty);
})*
} }
}
macro_rules! impl_writeable {
($st:ident, $len: expr, {$($field:ident),*}) => {
impl ::util::ser::Writeable for $st {
fn write<W: ::util::ser::Writer>(&self, w: &mut W) -> Result<(), $crate::io::Error> {
if $len != 0 {
w.size_hint($len);
}
#[cfg(any(test, feature = "fuzztarget"))]
{
// In tests, assert that the hard-coded length matches the actual one
if $len != 0 {
let mut len_calc = ::util::ser::LengthCalculatingWriter(0);
$( self.$field.write(&mut len_calc).expect("No in-memory data may fail to serialize"); )*
assert_eq!(len_calc.0, $len);
assert_eq!(self.serialized_length(), $len);
}
}
$( self.$field.write(w)?; )*
Ok(())
}
#[inline]
fn serialized_length(&self) -> usize {
if $len == 0 || cfg!(any(test, feature = "fuzztarget")) {
let mut len_calc = 0;
$( len_calc += self.$field.serialized_length(); )*
if $len != 0 {
// In tests, assert that the hard-coded length matches the actual one
assert_eq!(len_calc, $len);
} else {
return len_calc;
}
}
$len
}
}
impl ::util::ser::Readable for $st {
fn read<R: $crate::io::Read>(r: &mut R) -> Result<Self, ::ln::msgs::DecodeError> {
Ok(Self {
$($field: ::util::ser::Readable::read(r)?),*
})
}
}
}
}
macro_rules! impl_writeable_len_match {
($struct: ident, $cmp: tt, ($calc_len: expr), {$({$match: pat, $length: expr}),*}, {$($field:ident),*}) => {
impl Writeable for $struct {
fn write<W: Writer>(&self, w: &mut W) -> Result<(), $crate::io::Error> {
let len = match *self {
$($match => $length,)*
};
w.size_hint(len);
#[cfg(any(test, feature = "fuzztarget"))]
{
// In tests, assert that the hard-coded length matches the actual one
let mut len_calc = ::util::ser::LengthCalculatingWriter(0);
$( self.$field.write(&mut len_calc).expect("No in-memory data may fail to serialize"); )*
assert!(len_calc.0 $cmp len);
assert_eq!(len_calc.0, self.serialized_length());
}
$( self.$field.write(w)?; )*
Ok(())
}
#[inline]
fn serialized_length(&self) -> usize {
if $calc_len || cfg!(any(test, feature = "fuzztarget")) {
let mut len_calc = 0;
$( len_calc += self.$field.serialized_length(); )*
if !$calc_len {
assert_eq!(len_calc, match *self {
$($match => $length,)*
});
}
return len_calc
}
match *self {
$($match => $length,)*
}
}
}
impl ::util::ser::Readable for $struct {
fn read<R: $crate::io::Read>(r: &mut R) -> Result<Self, DecodeError> {
Ok(Self {
$($field: Readable::read(r)?),*
})
}
}
};
($struct: ident, $cmp: tt, {$({$match: pat, $length: expr}),*}, {$($field:ident),*}) => {
impl_writeable_len_match!($struct, $cmp, (true), { $({ $match, $length }),* }, { $($field),* });
};
($struct: ident, {$({$match: pat, $length: expr}),*}, {$($field:ident),*}) => {
impl_writeable_len_match!($struct, ==, (false), { $({ $match, $length }),* }, { $($field),* });
}
}
/// Write out two bytes to indicate the version of an object.
/// $this_version represents a unique version of a type. Incremented whenever the type's
/// serialization format has changed or has a new interpretation. Used by a type's
/// reader to determine how to interpret fields or if it can understand a serialized
/// object.
/// $min_version_that_can_read_this is the minimum reader version which can understand this
/// serialized object. Previous versions will simply err with a
/// DecodeError::UnknownVersion.
///
/// Updates to either $this_version or $min_version_that_can_read_this should be included in
/// release notes.
///
/// Both version fields can be specific to this type of object.
macro_rules! write_ver_prefix {
($stream: expr, $this_version: expr, $min_version_that_can_read_this: expr) => {
$stream.write_all(&[$this_version; 1])?;
$stream.write_all(&[$min_version_that_can_read_this; 1])?;
}
}
/// Writes out a suffix to an object which contains potentially backwards-compatible, optional
/// fields which old nodes can happily ignore.
///
/// It is written out in TLV format and, as with all TLV fields, unknown even fields cause a
/// DecodeError::UnknownRequiredFeature error, with unknown odd fields ignored.
///
/// This is the preferred method of adding new fields that old nodes can ignore and still function
/// correctly.
macro_rules! write_tlv_fields {
($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),* $(,)*}) => {
encode_varint_length_prefixed_tlv!($stream, {$(($type, $field, $fieldty)),*});
}
}
/// Reads a prefix added by write_ver_prefix!(), above. Takes the current version of the
/// serialization logic for this object. This is compared against the
/// $min_version_that_can_read_this added by write_ver_prefix!().
macro_rules! read_ver_prefix {
($stream: expr, $this_version: expr) => { {
let ver: u8 = Readable::read($stream)?;
let min_ver: u8 = Readable::read($stream)?;
if min_ver > $this_version {
return Err(DecodeError::UnknownVersion);
}
ver
} }
}
/// Reads a suffix added by write_tlv_fields.
macro_rules! read_tlv_fields {
($stream: expr, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => { {
let tlv_len: ::util::ser::BigSize = ::util::ser::Readable::read($stream)?;
let mut rd = ::util::ser::FixedLengthReader::new($stream, tlv_len.0);
decode_tlv_stream!(&mut rd, {$(($type, $field, $fieldty)),*});
rd.eat_remaining().map_err(|_| ::ln::msgs::DecodeError::ShortRead)?;
} }
}
macro_rules! init_tlv_based_struct_field {
($field: ident, (default_value, $default: expr)) => {
$field
};
($field: ident, option) => {
$field
};
($field: ident, required) => {
$field.0.unwrap()
};
($field: ident, vec_type) => {
$field.unwrap().0
};
}
macro_rules! init_tlv_field_var {
($field: ident, (default_value, $default: expr)) => {
let mut $field = $default;
};
($field: ident, required) => {
let mut $field = ::util::ser::OptionDeserWrapper(None);
};
($field: ident, vec_type) => {
let mut $field = Some(::util::ser::VecReadWrapper(Vec::new()));
};
($field: ident, option) => {
let mut $field = None;
};
}
/// Implements Readable/Writeable for a struct storing it as a set of TLVs
/// If $fieldty is `required`, then $field is a required field that is not an Option nor a Vec.
/// If $fieldty is `option`, then $field is optional field.
/// if $fieldty is `vec_type`, then $field is a Vec, which needs to have its individual elements
/// serialized.
macro_rules! impl_writeable_tlv_based {
($st: ident, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => {
impl ::util::ser::Writeable for $st {
fn write<W: ::util::ser::Writer>(&self, writer: &mut W) -> Result<(), $crate::io::Error> {
write_tlv_fields!(writer, {
$(($type, self.$field, $fieldty)),*
});
Ok(())
}
#[inline]
fn serialized_length(&self) -> usize {
use util::ser::BigSize;
let len = {
#[allow(unused_mut)]
let mut len = ::util::ser::LengthCalculatingWriter(0);
$(
get_varint_length_prefixed_tlv_length!(len, $type, self.$field, $fieldty);
)*
len.0
};
let mut len_calc = ::util::ser::LengthCalculatingWriter(0);
BigSize(len as u64).write(&mut len_calc).expect("No in-memory data may fail to serialize");
len + len_calc.0
}
}
impl ::util::ser::Readable for $st {
fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, ::ln::msgs::DecodeError> {
$(
init_tlv_field_var!($field, $fieldty);
)*
read_tlv_fields!(reader, {
$(($type, $field, $fieldty)),*
});
Ok(Self {
$(
$field: init_tlv_based_struct_field!($field, $fieldty)
),*
})
}
}
}
}
macro_rules! _impl_writeable_tlv_based_enum_common {
($st: ident, $(($variant_id: expr, $variant_name: ident) =>
{$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
),* $(,)*;
$(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*) => {
impl ::util::ser::Writeable for $st {
fn write<W: ::util::ser::Writer>(&self, writer: &mut W) -> Result<(), $crate::io::Error> {
match self {
$($st::$variant_name { $(ref $field),* } => {
let id: u8 = $variant_id;
id.write(writer)?;
write_tlv_fields!(writer, {
$(($type, $field, $fieldty)),*
});
}),*
$($st::$tuple_variant_name (ref field) => {
let id: u8 = $tuple_variant_id;
id.write(writer)?;
field.write(writer)?;
}),*
}
Ok(())
}
}
}
}
/// Implement MaybeReadable and Writeable for an enum, with struct variants stored as TLVs and
/// tuple variants stored directly.
///
/// This is largely identical to `impl_writeable_tlv_based_enum`, except that odd variants will
/// return `Ok(None)` instead of `Err(UnknownRequiredFeature)`. It should generally be preferred
/// when `MaybeReadable` is practical instead of just `Readable` as it provides an upgrade path for
/// new variants to be added which are simply ignored by existing clients.
macro_rules! impl_writeable_tlv_based_enum_upgradable {
($st: ident, $(($variant_id: expr, $variant_name: ident) =>
{$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
),* $(,)*) => {
_impl_writeable_tlv_based_enum_common!($st,
$(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*; );
impl ::util::ser::MaybeReadable for $st {
fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Option<Self>, ::ln::msgs::DecodeError> {
let id: u8 = ::util::ser::Readable::read(reader)?;
match id {
$($variant_id => {
// Because read_tlv_fields creates a labeled loop, we cannot call it twice
// in the same function body. Instead, we define a closure and call it.
let f = || {
$(
init_tlv_field_var!($field, $fieldty);
)*
read_tlv_fields!(reader, {
$(($type, $field, $fieldty)),*
});
Ok(Some($st::$variant_name {
$(
$field: init_tlv_based_struct_field!($field, $fieldty)
),*
}))
};
f()
}),*
_ if id % 2 == 1 => Ok(None),
_ => Err(DecodeError::UnknownRequiredFeature),
}
}
}
}
}
/// Implement Readable and Writeable for an enum, with struct variants stored as TLVs and tuple
/// variants stored directly.
/// The format is, for example
/// impl_writeable_tlv_based_enum!(EnumName,
/// (0, StructVariantA) => {(0, required_variant_field, required), (1, optional_variant_field, option)},
/// (1, StructVariantB) => {(0, variant_field_a, required), (1, variant_field_b, required), (2, variant_vec_field, vec_type)};
/// (2, TupleVariantA), (3, TupleVariantB),
/// );
/// The type is written as a single byte, followed by any variant data.
/// Attempts to read an unknown type byte result in DecodeError::UnknownRequiredFeature.
macro_rules! impl_writeable_tlv_based_enum {
($st: ident, $(($variant_id: expr, $variant_name: ident) =>
{$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
),* $(,)*;
$(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*) => {
_impl_writeable_tlv_based_enum_common!($st,
$(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*;
$(($tuple_variant_id, $tuple_variant_name)),*);
impl ::util::ser::Readable for $st {
fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, ::ln::msgs::DecodeError> {
let id: u8 = ::util::ser::Readable::read(reader)?;
match id {
$($variant_id => {
// Because read_tlv_fields creates a labeled loop, we cannot call it twice
// in the same function body. Instead, we define a closure and call it.
let f = || {
$(
init_tlv_field_var!($field, $fieldty);
)*
read_tlv_fields!(reader, {
$(($type, $field, $fieldty)),*
});
Ok($st::$variant_name {
$(
$field: init_tlv_based_struct_field!($field, $fieldty)
),*
})
};
f()
}),*
$($tuple_variant_id => {
Ok($st::$tuple_variant_name(Readable::read(reader)?))
}),*
_ => {
Err(DecodeError::UnknownRequiredFeature)
},
}
}
}
}
}
#[cfg(test)]
mod tests {
use io::{self, Cursor};
use prelude::*;
use ln::msgs::DecodeError;
use util::ser::{Writeable, HighZeroBytesDroppedVarInt, VecWriter};
use bitcoin::secp256k1::PublicKey;
// The BOLT TLV test cases don't include any tests which use our "required-value" logic since
// the encoding layer in the BOLTs has no such concept, though it makes our macros easier to
// work with so they're baked into the decoder. Thus, we have a few additional tests below
fn tlv_reader(s: &[u8]) -> Result<(u64, u32, Option<u32>), DecodeError> {
let mut s = Cursor::new(s);
let mut a: u64 = 0;
let mut b: u32 = 0;
let mut c: Option<u32> = None;
decode_tlv_stream!(&mut s, {(2, a, required), (3, b, required), (4, c, option)});
Ok((a, b, c))
}
#[test]
fn tlv_v_short_read() {
// We only expect a u32 for type 3 (which we are given), but the L says its 8 bytes.
if let Err(DecodeError::ShortRead) = tlv_reader(&::hex::decode(
concat!("0100", "0208deadbeef1badbeef", "0308deadbeef")
).unwrap()[..]) {
} else { panic!(); }
}
#[test]
fn tlv_types_out_of_order() {
if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
concat!("0100", "0304deadbeef", "0208deadbeef1badbeef")
).unwrap()[..]) {
} else { panic!(); }
// ...even if its some field we don't understand
if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
concat!("0208deadbeef1badbeef", "0100", "0304deadbeef")
).unwrap()[..]) {
} else { panic!(); }
}
#[test]
fn tlv_req_type_missing_or_extra() {
// It's also bad if they included even fields we don't understand
if let Err(DecodeError::UnknownRequiredFeature) = tlv_reader(&::hex::decode(
concat!("0100", "0208deadbeef1badbeef", "0304deadbeef", "0600")
).unwrap()[..]) {
} else { panic!(); }
// ... or if they're missing fields we need
if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
concat!("0100", "0208deadbeef1badbeef")
).unwrap()[..]) {
} else { panic!(); }
// ... even if that field is even
if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
concat!("0304deadbeef", "0500")
).unwrap()[..]) {
} else { panic!(); }
}
#[test]
fn tlv_simple_good_cases() {
assert_eq!(tlv_reader(&::hex::decode(
concat!("0208deadbeef1badbeef", "03041bad1dea")
).unwrap()[..]).unwrap(),
(0xdeadbeef1badbeef, 0x1bad1dea, None));
assert_eq!(tlv_reader(&::hex::decode(
concat!("0208deadbeef1badbeef", "03041bad1dea", "040401020304")
).unwrap()[..]).unwrap(),
(0xdeadbeef1badbeef, 0x1bad1dea, Some(0x01020304)));
}
// BOLT TLV test cases
fn tlv_reader_n1(s: &[u8]) -> Result<(Option<HighZeroBytesDroppedVarInt<u64>>, Option<u64>, Option<(PublicKey, u64, u64)>, Option<u16>), DecodeError> {
let mut s = Cursor::new(s);
let mut tlv1: Option<HighZeroBytesDroppedVarInt<u64>> = None;
let mut tlv2: Option<u64> = None;
let mut tlv3: Option<(PublicKey, u64, u64)> = None;
let mut tlv4: Option<u16> = None;
decode_tlv_stream!(&mut s, {(1, tlv1, option), (2, tlv2, option), (3, tlv3, option), (254, tlv4, option)});
Ok((tlv1, tlv2, tlv3, tlv4))
}
#[test]
fn bolt_tlv_bogus_stream() {
macro_rules! do_test {
($stream: expr, $reason: ident) => {
if let Err(DecodeError::$reason) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
} else { panic!(); }
}
}
// TLVs from the BOLT test cases which should not decode as either n1 or n2
do_test!(concat!("fd01"), ShortRead);
do_test!(concat!("fd0001", "00"), InvalidValue);
do_test!(concat!("fd0101"), ShortRead);
do_test!(concat!("0f", "fd"), ShortRead);
do_test!(concat!("0f", "fd26"), ShortRead);
do_test!(concat!("0f", "fd2602"), ShortRead);
do_test!(concat!("0f", "fd0001", "00"), InvalidValue);
do_test!(concat!("0f", "fd0201", "000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000"), ShortRead);
do_test!(concat!("12", "00"), UnknownRequiredFeature);
do_test!(concat!("fd0102", "00"), UnknownRequiredFeature);
do_test!(concat!("fe01000002", "00"), UnknownRequiredFeature);
do_test!(concat!("ff0100000000000002", "00"), UnknownRequiredFeature);
}
#[test]
fn bolt_tlv_bogus_n1_stream() {
macro_rules! do_test {
($stream: expr, $reason: ident) => {
if let Err(DecodeError::$reason) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
} else { panic!(); }
}
}
// TLVs from the BOLT test cases which should not decode as n1
do_test!(concat!("01", "09", "ffffffffffffffffff"), InvalidValue);
do_test!(concat!("01", "01", "00"), InvalidValue);
do_test!(concat!("01", "02", "0001"), InvalidValue);
do_test!(concat!("01", "03", "000100"), InvalidValue);
do_test!(concat!("01", "04", "00010000"), InvalidValue);
do_test!(concat!("01", "05", "0001000000"), InvalidValue);
do_test!(concat!("01", "06", "000100000000"), InvalidValue);
do_test!(concat!("01", "07", "00010000000000"), InvalidValue);
do_test!(concat!("01", "08", "0001000000000000"), InvalidValue);
do_test!(concat!("02", "07", "01010101010101"), ShortRead);
do_test!(concat!("02", "09", "010101010101010101"), InvalidValue);
do_test!(concat!("03", "21", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb"), ShortRead);
do_test!(concat!("03", "29", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb0000000000000001"), ShortRead);
do_test!(concat!("03", "30", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb000000000000000100000000000001"), ShortRead);
do_test!(concat!("03", "31", "043da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb00000000000000010000000000000002"), InvalidValue);
do_test!(concat!("03", "32", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb0000000000000001000000000000000001"), InvalidValue);
do_test!(concat!("fd00fe", "00"), ShortRead);
do_test!(concat!("fd00fe", "01", "01"), ShortRead);
do_test!(concat!("fd00fe", "03", "010101"), InvalidValue);
do_test!(concat!("00", "00"), UnknownRequiredFeature);
do_test!(concat!("02", "08", "0000000000000226", "01", "01", "2a"), InvalidValue);
do_test!(concat!("02", "08", "0000000000000231", "02", "08", "0000000000000451"), InvalidValue);
do_test!(concat!("1f", "00", "0f", "01", "2a"), InvalidValue);
do_test!(concat!("1f", "00", "1f", "01", "2a"), InvalidValue);
// The last BOLT test modified to not require creating a new decoder for one trivial test.
do_test!(concat!("ffffffffffffffffff", "00", "01", "00"), InvalidValue);
}
#[test]
fn bolt_tlv_valid_n1_stream() {
macro_rules! do_test {
($stream: expr, $tlv1: expr, $tlv2: expr, $tlv3: expr, $tlv4: expr) => {
if let Ok((tlv1, tlv2, tlv3, tlv4)) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
assert_eq!(tlv1.map(|v| v.0), $tlv1);
assert_eq!(tlv2, $tlv2);
assert_eq!(tlv3, $tlv3);
assert_eq!(tlv4, $tlv4);
} else { panic!(); }
}
}
do_test!(concat!(""), None, None, None, None);
do_test!(concat!("21", "00"), None, None, None, None);
do_test!(concat!("fd0201", "00"), None, None, None, None);
do_test!(concat!("fd00fd", "00"), None, None, None, None);
do_test!(concat!("fd00ff", "00"), None, None, None, None);
do_test!(concat!("fe02000001", "00"), None, None, None, None);
do_test!(concat!("ff0200000000000001", "00"), None, None, None, None);
do_test!(concat!("01", "00"), Some(0), None, None, None);
do_test!(concat!("01", "01", "01"), Some(1), None, None, None);
do_test!(concat!("01", "02", "0100"), Some(256), None, None, None);
do_test!(concat!("01", "03", "010000"), Some(65536), None, None, None);
do_test!(concat!("01", "04", "01000000"), Some(16777216), None, None, None);
do_test!(concat!("01", "05", "0100000000"), Some(4294967296), None, None, None);
do_test!(concat!("01", "06", "010000000000"), Some(1099511627776), None, None, None);
do_test!(concat!("01", "07", "01000000000000"), Some(281474976710656), None, None, None);
do_test!(concat!("01", "08", "0100000000000000"), Some(72057594037927936), None, None, None);
do_test!(concat!("02", "08", "0000000000000226"), None, Some((0 << 30) | (0 << 5) | (550 << 0)), None, None);
do_test!(concat!("03", "31", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb00000000000000010000000000000002"),
None, None, Some((
PublicKey::from_slice(&::hex::decode("023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb").unwrap()[..]).unwrap(), 1, 2)),
None);
do_test!(concat!("fd00fe", "02", "0226"), None, None, None, Some(550));
}
fn do_simple_test_tlv_write() -> Result<(), io::Error> {
let mut stream = VecWriter(Vec::new());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(1, 1u8, required), (42, None::<u64>, option)});
assert_eq!(stream.0, ::hex::decode("03010101").unwrap());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(1, Some(1u8), option)});
assert_eq!(stream.0, ::hex::decode("03010101").unwrap());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(4, 0xabcdu16, required), (42, None::<u64>, option)});
assert_eq!(stream.0, ::hex::decode("040402abcd").unwrap());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(42, None::<u64>, option), (0xff, 0xabcdu16, required)});
assert_eq!(stream.0, ::hex::decode("06fd00ff02abcd").unwrap());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(0, 1u64, required), (42, None::<u64>, option), (0xff, HighZeroBytesDroppedVarInt(0u64), required)});
assert_eq!(stream.0, ::hex::decode("0e00080000000000000001fd00ff00").unwrap());
stream.0.clear();
encode_varint_length_prefixed_tlv!(&mut stream, {(0, Some(1u64), option), (0xff, HighZeroBytesDroppedVarInt(0u64), required)});
assert_eq!(stream.0, ::hex::decode("0e00080000000000000001fd00ff00").unwrap());
Ok(())
}
#[test]
fn simple_test_tlv_write() {
do_simple_test_tlv_write().unwrap();
}
}