field.write($stream)?;
}
};
+ ($stream: expr, $type: expr, $field: expr, optional_vec) => {
+ if !$field.is_empty() {
+ $crate::_encode_tlv!($stream, $type, $field, vec_type);
+ }
+ };
+ ($stream: expr, $type: expr, $field: expr, upgradable_required) => {
+ $crate::_encode_tlv!($stream, $type, $field, required);
+ };
+ ($stream: expr, $type: expr, $field: expr, upgradable_option) => {
+ $crate::_encode_tlv!($stream, $type, $field, option);
+ };
($stream: expr, $type: expr, $field: expr, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
$crate::_encode_tlv!($stream, $type, $field.map(|f| $encoding(f)), option);
};
($stream: expr, $type: expr, $field: expr, (option, encoding: $fieldty: ty)) => {
$crate::_encode_tlv!($stream, $type, $field, option);
};
+ ($stream: expr, $type: expr, $field: expr, (option: $trait: ident $(, $read_arg: expr)?)) => {
+ // Just a read-mapped type
+ $crate::_encode_tlv!($stream, $type, $field, option);
+ };
}
/// Panics if the last seen TLV type is not numerically less than the TLV type currently being checked.
$len.0 += field_len;
}
};
+ ($len: expr, $type: expr, $field: expr, optional_vec) => {
+ if !$field.is_empty() {
+ $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, vec_type);
+ }
+ };
+ ($len: expr, $type: expr, $field: expr, (option: $trait: ident $(, $read_arg: expr)?)) => {
+ $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, option);
+ };
+ ($len: expr, $type: expr, $field: expr, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
+ $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field.map(|f| $encoding(f)), option);
+ };
+ ($len: expr, $type: expr, $field: expr, upgradable_required) => {
+ $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, required);
+ };
+ ($len: expr, $type: expr, $field: expr, upgradable_option) => {
+ $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, option);
+ };
}
/// See the documentation of [`write_tlv_fields`].
return Err(DecodeError::InvalidValue);
}
}};
+ ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
+ $crate::_check_decoded_tlv_order!($last_seen_type, $typ, $type, $field, required);
+ }};
($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, $field: ident, ignorable) => {{
+ ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, optional_vec) => {{
+ // no-op
+ }};
+ ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, upgradable_required) => {{
+ _check_decoded_tlv_order!($last_seen_type, $typ, $type, $field, required)
+ }};
+ ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, upgradable_option) => {{
// no-op
}};
($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
return Err(DecodeError::InvalidValue);
}
}};
+ ($last_seen_type: expr, $type: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
+ $crate::_check_missing_tlv!($last_seen_type, $type, $field, required);
+ }};
($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, $field: ident, ignorable) => {{
+ ($last_seen_type: expr, $type: expr, $field: ident, optional_vec) => {{
+ // no-op
+ }};
+ ($last_seen_type: expr, $type: expr, $field: ident, upgradable_required) => {{
+ _check_missing_tlv!($last_seen_type, $type, $field, required)
+ }};
+ ($last_seen_type: expr, $type: expr, $field: ident, upgradable_option) => {{
// no-op
}};
($last_seen_type: expr, $type: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
($reader: expr, $field: ident, required) => {{
$field = $crate::util::ser::Readable::read(&mut $reader)?;
}};
+ ($reader: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
+ $field = $trait::read(&mut $reader $(, $read_arg)*)?;
+ }};
($reader: expr, $field: ident, vec_type) => {{
let f: $crate::util::ser::WithoutLength<Vec<_>> = $crate::util::ser::Readable::read(&mut $reader)?;
$field = Some(f.0);
($reader: expr, $field: ident, option) => {{
$field = Some($crate::util::ser::Readable::read(&mut $reader)?);
}};
- ($reader: expr, $field: ident, ignorable) => {{
+ ($reader: expr, $field: ident, optional_vec) => {{
+ $crate::_decode_tlv!($reader, $field, vec_type);
+ }};
+ // `upgradable_required` indicates we're reading a required TLV that may have been upgraded
+ // without backwards compat. We'll error if the field is missing, and return `Ok(None)` if the
+ // field is present but we can no longer understand it.
+ // Note that this variant can only be used within a `MaybeReadable` read.
+ ($reader: expr, $field: ident, upgradable_required) => {{
+ $field = match $crate::util::ser::MaybeReadable::read(&mut $reader)? {
+ Some(res) => res,
+ _ => return Ok(None)
+ };
+ }};
+ // `upgradable_option` indicates we're reading an Option-al TLV that may have been upgraded
+ // without backwards compat. $field will be None if the TLV is missing or if the field is present
+ // but we can no longer understand it.
+ ($reader: expr, $field: ident, upgradable_option) => {{
$field = $crate::util::ser::MaybeReadable::read(&mut $reader)?;
}};
($reader: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
$field = Some($trait::read(&mut $reader $(, $read_arg)*)?);
}};
+ ($reader: expr, $field: ident, (option, encoding: ($fieldty: ty, $encoding: ident, $encoder:ty))) => {{
+ $crate::_decode_tlv!($reader, $field, (option, encoding: ($fieldty, $encoding)));
+ }};
($reader: expr, $field: ident, (option, encoding: ($fieldty: ty, $encoding: ident))) => {{
$field = {
let field: $encoding<$fieldty> = ser::Readable::read(&mut $reader)?;
macro_rules! _decode_tlv_stream_range {
($stream: expr, $range: expr, $rewind: ident, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
$(, $decode_custom_tlv: expr)?) => { {
- use core::ops::RangeBounds;
use $crate::ln::msgs::DecodeError;
let mut last_seen_type: Option<u64> = None;
let mut stream_ref = $stream;
}
},
Err(e) => return Err(e),
- Ok(t) => if $range.contains(&t.0) { t } else {
+ Ok(t) => if core::ops::RangeBounds::contains(&$range, &t.0) { t } else {
drop(tracking_reader);
// Assumes the type id is minimally encoded, which is enforced on read.
} }
}
+/// Implements [`Readable`]/[`Writeable`] for a message struct that may include non-TLV and
+/// TLV-encoded parts.
+///
+/// This is useful to implement a [`CustomMessageReader`].
+///
+/// Currently `$fieldty` may only be `option`, i.e., `$tlvfield` is optional field.
+///
+/// For example,
+/// ```
+/// # use lightning::impl_writeable_msg;
+/// struct MyCustomMessage {
+/// pub field_1: u32,
+/// pub field_2: bool,
+/// pub field_3: String,
+/// pub tlv_optional_integer: Option<u32>,
+/// }
+///
+/// impl_writeable_msg!(MyCustomMessage, {
+/// field_1,
+/// field_2,
+/// field_3
+/// }, {
+/// (1, tlv_optional_integer, option),
+/// });
+/// ```
+///
+/// [`Readable`]: crate::util::ser::Readable
+/// [`Writeable`]: crate::util::ser::Writeable
+/// [`CustomMessageReader`]: crate::ln::wire::CustomMessageReader
+#[macro_export]
macro_rules! impl_writeable_msg {
($st:ident, {$($field:ident),* $(,)*}, {$(($type: expr, $tlvfield: ident, $fieldty: tt)),* $(,)*}) => {
impl $crate::util::ser::Writeable for $st {
fn write<W: $crate::util::ser::Writer>(&self, w: &mut W) -> Result<(), $crate::io::Error> {
$( self.$field.write(w)?; )*
- encode_tlv_stream!(w, {$(($type, self.$tlvfield, $fieldty)),*});
+ $crate::encode_tlv_stream!(w, {$(($type, self.$tlvfield.as_ref(), $fieldty)),*});
Ok(())
}
}
impl $crate::util::ser::Readable for $st {
fn read<R: $crate::io::Read>(r: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
$(let $field = $crate::util::ser::Readable::read(r)?;)*
- $(_init_tlv_field_var!($tlvfield, $fieldty);)*
- decode_tlv_stream!(r, {$(($type, $tlvfield, $fieldty)),*});
+ $($crate::_init_tlv_field_var!($tlvfield, $fieldty);)*
+ $crate::decode_tlv_stream!(r, {$(($type, $tlvfield, $fieldty)),*});
Ok(Self {
$($field),*,
$($tlvfield),*
}
/// 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.
+/// 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.
+///
/// $min_version_that_can_read_this is the minimum reader version which can understand this
-/// serialized object. Previous versions will simply err with a
-/// [`DecodeError::UnknownVersion`].
+/// serialized object. Previous versions will simply err with a [`DecodeError::UnknownVersion`].
///
/// Updates to either `$this_version` or `$min_version_that_can_read_this` should be included in
/// release notes.
}
/// Initializes the struct fields.
+///
/// This is exported for use by other exported macros, do not use directly.
#[doc(hidden)]
#[macro_export]
($field: ident, option) => {
$field
};
+ ($field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {
+ $crate::_init_tlv_based_struct_field!($field, option)
+ };
+ ($field: ident, upgradable_required) => {
+ $field.0.unwrap()
+ };
+ ($field: ident, upgradable_option) => {
+ $field
+ };
($field: ident, required) => {
$field.0.unwrap()
};
($field: ident, vec_type) => {
$field.unwrap()
};
+ ($field: ident, optional_vec) => {
+ $field.unwrap()
+ };
}
/// Initializes the variable we are going to read the TLV into.
+///
/// This is exported for use by other exported macros, do not use directly.
#[doc(hidden)]
#[macro_export]
macro_rules! _init_tlv_field_var {
($field: ident, (default_value, $default: expr)) => {
- let mut $field = $crate::util::ser::OptionDeserWrapper(None);
+ let mut $field = $crate::util::ser::RequiredWrapper(None);
};
($field: ident, (static_value, $value: expr)) => {
let $field;
};
($field: ident, required) => {
- let mut $field = $crate::util::ser::OptionDeserWrapper(None);
+ let mut $field = $crate::util::ser::RequiredWrapper(None);
+ };
+ ($field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {
+ $crate::_init_tlv_field_var!($field, required);
};
($field: ident, vec_type) => {
let mut $field = Some(Vec::new());
($field: ident, option) => {
let mut $field = None;
};
+ ($field: ident, optional_vec) => {
+ let mut $field = Some(Vec::new());
+ };
+ ($field: ident, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
+ $crate::_init_tlv_field_var!($field, option);
+ };
+ ($field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {
+ $crate::_init_tlv_field_var!($field, option);
+ };
+ ($field: ident, upgradable_required) => {
+ let mut $field = $crate::util::ser::UpgradableRequired(None);
+ };
+ ($field: ident, upgradable_option) => {
+ let mut $field = None;
+ };
}
/// Equivalent to running [`_init_tlv_field_var`] then [`read_tlv_fields`].
+///
/// This is exported for use by other exported macros, do not use directly.
#[doc(hidden)]
#[macro_export]
}
/// Implements [`Readable`]/[`Writeable`] for a struct storing it as a set of TLVs
-/// If `$fieldty` is `required`, then `$field` is a required field that is not an Option nor a Vec.
+/// If `$fieldty` is `required`, then `$field` is a required field that is not an [`Option`] nor a [`Vec`].
/// If `$fieldty` is `(default_value, $default)`, then `$field` will be set to `$default` if not present.
/// If `$fieldty` is `option`, then `$field` is optional field.
-/// If `$fieldty` is `vec_type`, then `$field` is a Vec, which needs to have its individual elements serialized.
+/// If `$fieldty` is `optional_vec`, then `$field` is a [`Vec`], which needs to have its individual elements serialized.
+/// Note that for `optional_vec` no bytes are written if the vec is empty
///
/// For example,
/// ```
/// (0, tlv_integer, required),
/// (1, tlv_default_integer, (default_value, 7)),
/// (2, tlv_optional_integer, option),
-/// (3, tlv_vec_type_integer, vec_type),
+/// (3, tlv_vec_type_integer, optional_vec),
/// });
/// ```
///
)*
}
- #[derive(Debug, PartialEq)]
+ #[cfg_attr(test, derive(PartialEq))]
+ #[derive(Debug)]
pub(super) struct $nameref<'a> {
$(
pub(super) $field: Option<tlv_record_ref_type!($fieldty)>,
macro_rules! tlv_record_type {
(($type:ty, $wrapper:ident)) => { $type };
+ (($type:ty, $wrapper:ident, $encoder:ty)) => { $type };
($type:ty) => { $type };
}
((u32, $wrapper: ident)) => { u32 };
((u64, $wrapper: ident)) => { u64 };
(($type:ty, $wrapper:ident)) => { &'a $type };
+ (($type:ty, $wrapper:ident, $encoder:ty)) => { $encoder };
($type:ty) => { &'a $type };
}
+#[doc(hidden)]
+#[macro_export]
macro_rules! _impl_writeable_tlv_based_enum_common {
($st: ident, $(($variant_id: expr, $variant_name: ident) =>
{$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
$($st::$variant_name { $(ref $field),* } => {
let id: u8 = $variant_id;
id.write(writer)?;
- write_tlv_fields!(writer, {
+ $crate::write_tlv_fields!(writer, {
$(($type, *$field, $fieldty)),*
});
}),*
}
}
-/// Implement [`MaybeReadable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and
-/// tuple variants stored directly.
-///
-/// This is largely identical to [`impl_writeable_tlv_based_enum`], except that odd variants will
-/// return `Ok(None)` instead of `Err(`[`DecodeError::UnknownRequiredFeature`]`)`. It should generally be preferred
-/// when [`MaybeReadable`] is practical instead of just [`Readable`] as it provides an upgrade path for
-/// new variants to be added which are simply ignored by existing clients.
+/// Implement [`Readable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and tuple
+/// variants stored directly.
+/// The format is, for example
+/// ```ignore
+/// impl_writeable_tlv_based_enum!(EnumName,
+/// (0, StructVariantA) => {(0, required_variant_field, required), (1, optional_variant_field, option)},
+/// (1, StructVariantB) => {(0, variant_field_a, required), (1, variant_field_b, required), (2, variant_vec_field, optional_vec)};
+/// (2, TupleVariantA), (3, TupleVariantB),
+/// );
+/// ```
+/// The type is written as a single byte, followed by any variant data.
+/// Attempts to read an unknown type byte result in [`DecodeError::UnknownRequiredFeature`].
///
-/// [`MaybeReadable`]: crate::util::ser::MaybeReadable
+/// [`Readable`]: crate::util::ser::Readable
/// [`Writeable`]: crate::util::ser::Writeable
/// [`DecodeError::UnknownRequiredFeature`]: crate::ln::msgs::DecodeError::UnknownRequiredFeature
-/// [`Readable`]: crate::util::ser::Readable
-macro_rules! impl_writeable_tlv_based_enum_upgradable {
+#[macro_export]
+macro_rules! impl_writeable_tlv_based_enum {
($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,
+ ),* $(,)*;
+ $(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*) => {
+ $crate::_impl_writeable_tlv_based_enum_common!($st,
$(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*;
- $($(($tuple_variant_id, $tuple_variant_name)),*)*);
+ $(($tuple_variant_id, $tuple_variant_name)),*);
- impl $crate::util::ser::MaybeReadable for $st {
- fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Option<Self>, $crate::ln::msgs::DecodeError> {
+ impl $crate::util::ser::Readable for $st {
+ fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
let id: u8 = $crate::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_and_read_tlv_fields!(reader, {
+ $crate::_init_and_read_tlv_fields!(reader, {
$(($type, $field, $fieldty)),*
});
- Ok(Some($st::$variant_name {
+ Ok($st::$variant_name {
$(
- $field: _init_tlv_based_struct_field!($field, $fieldty)
+ $field: $crate::_init_tlv_based_struct_field!($field, $fieldty)
),*
- }))
+ })
};
f()
}),*
- $($($tuple_variant_id => {
- Ok(Some($st::$tuple_variant_name(Readable::read(reader)?)))
- }),*)*
- _ if id % 2 == 1 => Ok(None),
- _ => Err(DecodeError::UnknownRequiredFeature),
+ $($tuple_variant_id => {
+ Ok($st::$tuple_variant_name(Readable::read(reader)?))
+ }),*
+ _ => {
+ Err($crate::ln::msgs::DecodeError::UnknownRequiredFeature)
+ },
}
}
}
-
}
}
-/// Implement [`Readable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and tuple
-/// variants stored directly.
-/// The format is, for example
-/// impl_writeable_tlv_based_enum!(EnumName,
-/// (0, StructVariantA) => {(0, required_variant_field, required), (1, optional_variant_field, option)},
-/// (1, StructVariantB) => {(0, variant_field_a, required), (1, variant_field_b, required), (2, variant_vec_field, vec_type)};
-/// (2, TupleVariantA), (3, TupleVariantB),
-/// );
-/// The type is written as a single byte, followed by any variant data.
-/// Attempts to read an unknown type byte result in [`DecodeError::UnknownRequiredFeature`].
+/// Implement [`MaybeReadable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and
+/// tuple variants stored directly.
///
-/// [`Readable`]: crate::util::ser::Readable
+/// This is largely identical to [`impl_writeable_tlv_based_enum`], except that odd variants will
+/// return `Ok(None)` instead of `Err(`[`DecodeError::UnknownRequiredFeature`]`)`. It should generally be preferred
+/// when [`MaybeReadable`] is practical instead of just [`Readable`] as it provides an upgrade path for
+/// new variants to be added which are simply ignored by existing clients.
+///
+/// [`MaybeReadable`]: crate::util::ser::MaybeReadable
/// [`Writeable`]: crate::util::ser::Writeable
/// [`DecodeError::UnknownRequiredFeature`]: crate::ln::msgs::DecodeError::UnknownRequiredFeature
-macro_rules! impl_writeable_tlv_based_enum {
+/// [`Readable`]: crate::util::ser::Readable
+#[macro_export]
+macro_rules! impl_writeable_tlv_based_enum_upgradable {
($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,
+ ),* $(,)*
+ $(;
+ $(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*)*) => {
+ $crate::_impl_writeable_tlv_based_enum_common!($st,
$(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*;
- $(($tuple_variant_id, $tuple_variant_name)),*);
+ $($(($tuple_variant_id, $tuple_variant_name)),*)*);
- impl $crate::util::ser::Readable for $st {
- fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
+ impl $crate::util::ser::MaybeReadable for $st {
+ fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Option<Self>, $crate::ln::msgs::DecodeError> {
let id: u8 = $crate::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_and_read_tlv_fields!(reader, {
+ $crate::_init_and_read_tlv_fields!(reader, {
$(($type, $field, $fieldty)),*
});
- Ok($st::$variant_name {
+ Ok(Some($st::$variant_name {
$(
- $field: _init_tlv_based_struct_field!($field, $fieldty)
+ $field: $crate::_init_tlv_based_struct_field!($field, $fieldty)
),*
- })
+ }))
};
f()
}),*
- $($tuple_variant_id => {
- Ok($st::$tuple_variant_name(Readable::read(reader)?))
- }),*
- _ => {
- Err($crate::ln::msgs::DecodeError::UnknownRequiredFeature)
- },
+ $($($tuple_variant_id => {
+ Ok(Some($st::$tuple_variant_name(Readable::read(reader)?)))
+ }),*)*
+ _ if id % 2 == 1 => Ok(None),
+ _ => Err($crate::ln::msgs::DecodeError::UnknownRequiredFeature),
}
}
}
(0xdeadbeef1badbeef, 0x1bad1dea, Some(0x01020304)));
}
+ #[derive(Debug, PartialEq)]
+ struct TestUpgradable {
+ a: u32,
+ b: u32,
+ c: Option<u32>,
+ }
+
+ fn upgradable_tlv_reader(s: &[u8]) -> Result<Option<TestUpgradable>, DecodeError> {
+ let mut s = Cursor::new(s);
+ let mut a = 0;
+ let mut b = 0;
+ let mut c: Option<u32> = None;
+ decode_tlv_stream!(&mut s, {(2, a, upgradable_required), (3, b, upgradable_required), (4, c, upgradable_option)});
+ Ok(Some(TestUpgradable { a, b, c, }))
+ }
+
+ #[test]
+ fn upgradable_tlv_simple_good_cases() {
+ assert_eq!(upgradable_tlv_reader(&::hex::decode(
+ concat!("0204deadbeef", "03041bad1dea", "0404deadbeef")
+ ).unwrap()[..]).unwrap(),
+ Some(TestUpgradable { a: 0xdeadbeef, b: 0x1bad1dea, c: Some(0xdeadbeef) }));
+
+ assert_eq!(upgradable_tlv_reader(&::hex::decode(
+ concat!("0204deadbeef", "03041bad1dea")
+ ).unwrap()[..]).unwrap(),
+ Some(TestUpgradable { a: 0xdeadbeef, b: 0x1bad1dea, c: None}));
+ }
+
+ #[test]
+ fn missing_required_upgradable() {
+ if let Err(DecodeError::InvalidValue) = upgradable_tlv_reader(&::hex::decode(
+ concat!("0100", "0204deadbeef")
+ ).unwrap()[..]) {
+ } else { panic!(); }
+ if let Err(DecodeError::InvalidValue) = upgradable_tlv_reader(&::hex::decode(
+ concat!("0100", "03041bad1dea")
+ ).unwrap()[..]) {
+ } else { panic!(); }
+ }
+
// BOLT TLV test cases
fn tlv_reader_n1(s: &[u8]) -> Result<(Option<HighZeroBytesDroppedBigSize<u64>>, Option<u64>, Option<(PublicKey, u64, u64)>, Option<u16>), DecodeError> {
let mut s = Cursor::new(s);