1 // This file is Copyright its original authors, visible in version control
4 // This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
5 // or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
6 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
7 // You may not use this file except in accordance with one or both of these
10 //! Some macros that implement [`Readable`]/[`Writeable`] traits for lightning messages.
11 //! They also handle serialization and deserialization of TLVs.
13 //! [`Readable`]: crate::util::ser::Readable
14 //! [`Writeable`]: crate::util::ser::Writeable
16 /// Implements serialization for a single TLV record.
17 /// This is exported for use by other exported macros, do not use directly.
20 macro_rules! _encode_tlv {
21 ($stream: expr, $type: expr, $field: expr, (default_value, $default: expr)) => {
22 $crate::_encode_tlv!($stream, $type, $field, required)
24 ($stream: expr, $type: expr, $field: expr, (static_value, $value: expr)) => {
25 let _ = &$field; // Ensure we "use" the $field
27 ($stream: expr, $type: expr, $field: expr, required) => {
28 BigSize($type).write($stream)?;
29 BigSize($field.serialized_length() as u64).write($stream)?;
30 $field.write($stream)?;
32 ($stream: expr, $type: expr, $field: expr, required_vec) => {
33 $crate::_encode_tlv!($stream, $type, $crate::util::ser::WithoutLength(&$field), required);
35 ($stream: expr, $optional_type: expr, $optional_field: expr, option) => {
36 if let Some(ref field) = $optional_field {
37 BigSize($optional_type).write($stream)?;
38 BigSize(field.serialized_length() as u64).write($stream)?;
39 field.write($stream)?;
42 ($stream: expr, $type: expr, $field: expr, optional_vec) => {
43 if !$field.is_empty() {
44 $crate::_encode_tlv!($stream, $type, $field, required_vec);
47 ($stream: expr, $type: expr, $field: expr, upgradable_required) => {
48 $crate::_encode_tlv!($stream, $type, $field, required);
50 ($stream: expr, $type: expr, $field: expr, upgradable_option) => {
51 $crate::_encode_tlv!($stream, $type, $field, option);
53 ($stream: expr, $type: expr, $field: expr, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
54 $crate::_encode_tlv!($stream, $type, $field.map(|f| $encoding(f)), option);
56 ($stream: expr, $type: expr, $field: expr, (option, encoding: $fieldty: ty)) => {
57 $crate::_encode_tlv!($stream, $type, $field, option);
59 ($stream: expr, $type: expr, $field: expr, (option: $trait: ident $(, $read_arg: expr)?)) => {
60 // Just a read-mapped type
61 $crate::_encode_tlv!($stream, $type, $field, option);
65 /// Panics if the last seen TLV type is not numerically less than the TLV type currently being checked.
66 /// This is exported for use by other exported macros, do not use directly.
69 macro_rules! _check_encoded_tlv_order {
70 ($last_type: expr, $type: expr, (static_value, $value: expr)) => { };
71 ($last_type: expr, $type: expr, $fieldty: tt) => {
72 if let Some(t) = $last_type {
73 #[allow(unused_comparisons)] // Note that $type may be 0 making the following comparison always false
74 (debug_assert!(t < $type))
76 $last_type = Some($type);
80 /// Implements the TLVs serialization part in a [`Writeable`] implementation of a struct.
82 /// This should be called inside a method which returns `Result<_, `[`io::Error`]`>`, such as
83 /// [`Writeable::write`]. It will only return an `Err` if the stream `Err`s or [`Writeable::write`]
84 /// on one of the fields `Err`s.
86 /// `$stream` must be a `&mut `[`Writer`] which will receive the bytes for each TLV in the stream.
88 /// Fields MUST be sorted in `$type`-order.
90 /// Note that the lightning TLV requirements require that a single type not appear more than once,
91 /// that TLVs are sorted in type-ascending order, and that any even types be understood by the
94 /// Any `option` fields which have a value of `None` will not be serialized at all.
98 /// # use lightning::encode_tlv_stream;
99 /// # fn write<W: lightning::util::ser::Writer> (stream: &mut W) -> Result<(), lightning::io::Error> {
100 /// let mut required_value = 0u64;
101 /// let mut optional_value: Option<u64> = None;
102 /// encode_tlv_stream!(stream, {
103 /// (0, required_value, required),
104 /// (1, Some(42u64), option),
105 /// (2, optional_value, option),
107 /// // At this point `required_value` has been written as a TLV of type 0, `42u64` has been written
108 /// // as a TLV of type 1 (indicating the reader may ignore it if it is not understood), and *no*
109 /// // TLV is written with type 2.
114 /// [`Writeable`]: crate::util::ser::Writeable
115 /// [`io::Error`]: crate::io::Error
116 /// [`Writeable::write`]: crate::util::ser::Writeable::write
117 /// [`Writer`]: crate::util::ser::Writer
119 macro_rules! encode_tlv_stream {
120 ($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),* $(,)*}) => { {
121 #[allow(unused_imports)]
123 ln::msgs::DecodeError,
126 util::ser::Writeable,
130 $crate::_encode_tlv!($stream, $type, $field, $fieldty);
133 #[allow(unused_mut, unused_variables, unused_assignments)]
134 #[cfg(debug_assertions)]
136 let mut last_seen: Option<u64> = None;
138 $crate::_check_encoded_tlv_order!(last_seen, $type, $fieldty);
144 /// Adds the length of the serialized field to a [`LengthCalculatingWriter`].
145 /// This is exported for use by other exported macros, do not use directly.
147 /// [`LengthCalculatingWriter`]: crate::util::ser::LengthCalculatingWriter
150 macro_rules! _get_varint_length_prefixed_tlv_length {
151 ($len: expr, $type: expr, $field: expr, (default_value, $default: expr)) => {
152 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, required)
154 ($len: expr, $type: expr, $field: expr, (static_value, $value: expr)) => {
156 ($len: expr, $type: expr, $field: expr, required) => {
157 BigSize($type).write(&mut $len).expect("No in-memory data may fail to serialize");
158 let field_len = $field.serialized_length();
159 BigSize(field_len as u64).write(&mut $len).expect("No in-memory data may fail to serialize");
162 ($len: expr, $type: expr, $field: expr, required_vec) => {
163 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $crate::util::ser::WithoutLength(&$field), required);
165 ($len: expr, $optional_type: expr, $optional_field: expr, option) => {
166 if let Some(ref field) = $optional_field {
167 BigSize($optional_type).write(&mut $len).expect("No in-memory data may fail to serialize");
168 let field_len = field.serialized_length();
169 BigSize(field_len as u64).write(&mut $len).expect("No in-memory data may fail to serialize");
173 ($len: expr, $type: expr, $field: expr, optional_vec) => {
174 if !$field.is_empty() {
175 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, required_vec);
178 ($len: expr, $type: expr, $field: expr, (option: $trait: ident $(, $read_arg: expr)?)) => {
179 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, option);
181 ($len: expr, $type: expr, $field: expr, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
182 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field.map(|f| $encoding(f)), option);
184 ($len: expr, $type: expr, $field: expr, upgradable_required) => {
185 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, required);
187 ($len: expr, $type: expr, $field: expr, upgradable_option) => {
188 $crate::_get_varint_length_prefixed_tlv_length!($len, $type, $field, option);
192 /// See the documentation of [`write_tlv_fields`].
193 /// This is exported for use by other exported macros, do not use directly.
196 macro_rules! _encode_varint_length_prefixed_tlv {
197 ($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),*}) => { {
198 use $crate::util::ser::BigSize;
201 let mut len = $crate::util::ser::LengthCalculatingWriter(0);
203 $crate::_get_varint_length_prefixed_tlv_length!(len, $type, $field, $fieldty);
207 BigSize(len as u64).write($stream)?;
208 $crate::encode_tlv_stream!($stream, { $(($type, $field, $fieldty)),* });
212 /// Errors if there are missing required TLV types between the last seen type and the type currently being processed.
213 /// This is exported for use by other exported macros, do not use directly.
216 macro_rules! _check_decoded_tlv_order {
217 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (default_value, $default: expr)) => {{
218 #[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always false
219 let invalid_order = ($last_seen_type.is_none() || $last_seen_type.unwrap() < $type) && $typ.0 > $type;
221 $field = $default.into();
224 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (static_value, $value: expr)) => {
226 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, required) => {{
227 #[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always false
228 let invalid_order = ($last_seen_type.is_none() || $last_seen_type.unwrap() < $type) && $typ.0 > $type;
230 return Err(DecodeError::InvalidValue);
233 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
234 $crate::_check_decoded_tlv_order!($last_seen_type, $typ, $type, $field, required);
236 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, option) => {{
239 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, required_vec) => {{
240 $crate::_check_decoded_tlv_order!($last_seen_type, $typ, $type, $field, required);
242 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, optional_vec) => {{
245 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, upgradable_required) => {{
246 _check_decoded_tlv_order!($last_seen_type, $typ, $type, $field, required)
248 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, upgradable_option) => {{
251 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
254 ($last_seen_type: expr, $typ: expr, $type: expr, $field: ident, (option, encoding: $encoding: tt)) => {{
259 /// Errors if there are missing required TLV types after the last seen type.
260 /// This is exported for use by other exported macros, do not use directly.
263 macro_rules! _check_missing_tlv {
264 ($last_seen_type: expr, $type: expr, $field: ident, (default_value, $default: expr)) => {{
265 #[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always false
266 let missing_req_type = $last_seen_type.is_none() || $last_seen_type.unwrap() < $type;
267 if missing_req_type {
268 $field = $default.into();
271 ($last_seen_type: expr, $type: expr, $field: expr, (static_value, $value: expr)) => {
274 ($last_seen_type: expr, $type: expr, $field: ident, required) => {{
275 #[allow(unused_comparisons)] // Note that $type may be 0 making the second comparison always false
276 let missing_req_type = $last_seen_type.is_none() || $last_seen_type.unwrap() < $type;
277 if missing_req_type {
278 return Err(DecodeError::InvalidValue);
281 ($last_seen_type: expr, $type: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
282 $crate::_check_missing_tlv!($last_seen_type, $type, $field, required);
284 ($last_seen_type: expr, $type: expr, $field: ident, required_vec) => {{
285 $crate::_check_missing_tlv!($last_seen_type, $type, $field, required);
287 ($last_seen_type: expr, $type: expr, $field: ident, option) => {{
290 ($last_seen_type: expr, $type: expr, $field: ident, optional_vec) => {{
293 ($last_seen_type: expr, $type: expr, $field: ident, upgradable_required) => {{
294 _check_missing_tlv!($last_seen_type, $type, $field, required)
296 ($last_seen_type: expr, $type: expr, $field: ident, upgradable_option) => {{
299 ($last_seen_type: expr, $type: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
302 ($last_seen_type: expr, $type: expr, $field: ident, (option, encoding: $encoding: tt)) => {{
307 /// Implements deserialization for a single TLV record.
308 /// This is exported for use by other exported macros, do not use directly.
311 macro_rules! _decode_tlv {
312 ($reader: expr, $field: ident, (default_value, $default: expr)) => {{
313 $crate::_decode_tlv!($reader, $field, required)
315 ($reader: expr, $field: ident, (static_value, $value: expr)) => {{
317 ($reader: expr, $field: ident, required) => {{
318 $field = $crate::util::ser::Readable::read(&mut $reader)?;
320 ($reader: expr, $field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {{
321 $field = $trait::read(&mut $reader $(, $read_arg)*)?;
323 ($reader: expr, $field: ident, required_vec) => {{
324 let f: $crate::util::ser::WithoutLength<Vec<_>> = $crate::util::ser::Readable::read(&mut $reader)?;
327 ($reader: expr, $field: ident, option) => {{
328 $field = Some($crate::util::ser::Readable::read(&mut $reader)?);
330 ($reader: expr, $field: ident, optional_vec) => {{
331 let f: $crate::util::ser::WithoutLength<Vec<_>> = $crate::util::ser::Readable::read(&mut $reader)?;
334 // `upgradable_required` indicates we're reading a required TLV that may have been upgraded
335 // without backwards compat. We'll error if the field is missing, and return `Ok(None)` if the
336 // field is present but we can no longer understand it.
337 // Note that this variant can only be used within a `MaybeReadable` read.
338 ($reader: expr, $field: ident, upgradable_required) => {{
339 $field = match $crate::util::ser::MaybeReadable::read(&mut $reader)? {
344 // `upgradable_option` indicates we're reading an Option-al TLV that may have been upgraded
345 // without backwards compat. $field will be None if the TLV is missing or if the field is present
346 // but we can no longer understand it.
347 ($reader: expr, $field: ident, upgradable_option) => {{
348 $field = $crate::util::ser::MaybeReadable::read(&mut $reader)?;
350 ($reader: expr, $field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {{
351 $field = Some($trait::read(&mut $reader $(, $read_arg)*)?);
353 ($reader: expr, $field: ident, (option, encoding: ($fieldty: ty, $encoding: ident, $encoder:ty))) => {{
354 $crate::_decode_tlv!($reader, $field, (option, encoding: ($fieldty, $encoding)));
356 ($reader: expr, $field: ident, (option, encoding: ($fieldty: ty, $encoding: ident))) => {{
358 let field: $encoding<$fieldty> = ser::Readable::read(&mut $reader)?;
362 ($reader: expr, $field: ident, (option, encoding: $fieldty: ty)) => {{
363 $crate::_decode_tlv!($reader, $field, option);
367 /// Checks if `$val` matches `$type`.
368 /// This is exported for use by other exported macros, do not use directly.
371 macro_rules! _decode_tlv_stream_match_check {
372 ($val: ident, $type: expr, (static_value, $value: expr)) => { false };
373 ($val: ident, $type: expr, $fieldty: tt) => { $val == $type }
376 /// Implements the TLVs deserialization part in a [`Readable`] implementation of a struct.
378 /// This should be called inside a method which returns `Result<_, `[`DecodeError`]`>`, such as
379 /// [`Readable::read`]. It will either return an `Err` or ensure all `required` fields have been
380 /// read and optionally read `optional` fields.
382 /// `$stream` must be a [`Read`] and will be fully consumed, reading until no more bytes remain
383 /// (i.e. it returns [`DecodeError::ShortRead`]).
385 /// Fields MUST be sorted in `$type`-order.
387 /// Note that the lightning TLV requirements require that a single type not appear more than once,
388 /// that TLVs are sorted in type-ascending order, and that any even types be understood by the
393 /// # use lightning::decode_tlv_stream;
394 /// # fn read<R: lightning::io::Read> (stream: R) -> Result<(), lightning::ln::msgs::DecodeError> {
395 /// let mut required_value = 0u64;
396 /// let mut optional_value: Option<u64> = None;
397 /// decode_tlv_stream!(stream, {
398 /// (0, required_value, required),
399 /// (2, optional_value, option),
401 /// // At this point, `required_value` has been overwritten with the TLV with type 0.
402 /// // `optional_value` may have been overwritten, setting it to `Some` if a TLV with type 2 was
408 /// [`Readable`]: crate::util::ser::Readable
409 /// [`DecodeError`]: crate::ln::msgs::DecodeError
410 /// [`Readable::read`]: crate::util::ser::Readable::read
411 /// [`Read`]: crate::io::Read
412 /// [`DecodeError::ShortRead`]: crate::ln::msgs::DecodeError::ShortRead
414 macro_rules! decode_tlv_stream {
415 ($stream: expr, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => {
416 let rewind = |_, _| { unreachable!() };
417 $crate::_decode_tlv_stream_range!($stream, .., rewind, {$(($type, $field, $fieldty)),*});
421 /// Similar to [`decode_tlv_stream`] with a custom TLV decoding capabilities.
423 /// `$decode_custom_tlv` is a closure that may be optionally provided to handle custom message types.
424 /// If it is provided, it will be called with the custom type and the [`FixedLengthReader`] containing
425 /// the message contents. It should return `Ok(true)` if the custom message is successfully parsed,
426 /// `Ok(false)` if the message type is unknown, and `Err(`[`DecodeError`]`)` if parsing fails.
428 /// [`FixedLengthReader`]: crate::util::ser::FixedLengthReader
429 /// [`DecodeError`]: crate::ln::msgs::DecodeError
430 macro_rules! decode_tlv_stream_with_custom_tlv_decode {
431 ($stream: expr, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
432 $(, $decode_custom_tlv: expr)?) => { {
433 let rewind = |_, _| { unreachable!() };
434 _decode_tlv_stream_range!(
435 $stream, .., rewind, {$(($type, $field, $fieldty)),*} $(, $decode_custom_tlv)?
442 macro_rules! _decode_tlv_stream_range {
443 ($stream: expr, $range: expr, $rewind: ident, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
444 $(, $decode_custom_tlv: expr)?) => { {
445 use $crate::ln::msgs::DecodeError;
446 let mut last_seen_type: Option<u64> = None;
447 let mut stream_ref = $stream;
449 use $crate::util::ser;
451 // First decode the type of this TLV:
452 let typ: ser::BigSize = {
453 // We track whether any bytes were read during the consensus_decode call to
454 // determine whether we should break or return ShortRead if we get an
455 // UnexpectedEof. This should in every case be largely cosmetic, but its nice to
456 // pass the TLV test vectors exactly, which require this distinction.
457 let mut tracking_reader = ser::ReadTrackingReader::new(&mut stream_ref);
458 match <$crate::util::ser::BigSize as $crate::util::ser::Readable>::read(&mut tracking_reader) {
459 Err(DecodeError::ShortRead) => {
460 if !tracking_reader.have_read {
463 return Err(DecodeError::ShortRead);
466 Err(e) => return Err(e),
467 Ok(t) => if core::ops::RangeBounds::contains(&$range, &t.0) { t } else {
468 drop(tracking_reader);
470 // Assumes the type id is minimally encoded, which is enforced on read.
471 use $crate::util::ser::Writeable;
472 let bytes_read = t.serialized_length();
473 $rewind(stream_ref, bytes_read);
479 // Types must be unique and monotonically increasing:
480 match last_seen_type {
481 Some(t) if typ.0 <= t => {
482 return Err(DecodeError::InvalidValue);
486 // As we read types, make sure we hit every required type between `last_seen_type` and `typ`:
488 $crate::_check_decoded_tlv_order!(last_seen_type, typ, $type, $field, $fieldty);
490 last_seen_type = Some(typ.0);
492 // Finally, read the length and value itself:
493 let length: ser::BigSize = $crate::util::ser::Readable::read(&mut stream_ref)?;
494 let mut s = ser::FixedLengthReader::new(&mut stream_ref, length.0);
496 $(_t if $crate::_decode_tlv_stream_match_check!(_t, $type, $fieldty) => {
497 $crate::_decode_tlv!(s, $field, $fieldty);
498 if s.bytes_remain() {
499 s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
500 return Err(DecodeError::InvalidValue);
505 if $decode_custom_tlv(t, &mut s)? {
506 // If a custom TLV was successfully read (i.e. decode_custom_tlv returns true),
507 // continue to the next TLV read.
513 return Err(DecodeError::UnknownRequiredFeature);
519 // Make sure we got to each required type after we've read every TLV:
521 $crate::_check_missing_tlv!(last_seen_type, $type, $field, $fieldty);
526 /// Implements [`Readable`]/[`Writeable`] for a message struct that may include non-TLV and
527 /// TLV-encoded parts.
529 /// This is useful to implement a [`CustomMessageReader`].
531 /// Currently `$fieldty` may only be `option`, i.e., `$tlvfield` is optional field.
535 /// # use lightning::impl_writeable_msg;
536 /// struct MyCustomMessage {
537 /// pub field_1: u32,
538 /// pub field_2: bool,
539 /// pub field_3: String,
540 /// pub tlv_optional_integer: Option<u32>,
543 /// impl_writeable_msg!(MyCustomMessage, {
548 /// (1, tlv_optional_integer, option),
552 /// [`Readable`]: crate::util::ser::Readable
553 /// [`Writeable`]: crate::util::ser::Writeable
554 /// [`CustomMessageReader`]: crate::ln::wire::CustomMessageReader
556 macro_rules! impl_writeable_msg {
557 ($st:ident, {$($field:ident),* $(,)*}, {$(($type: expr, $tlvfield: ident, $fieldty: tt)),* $(,)*}) => {
558 impl $crate::util::ser::Writeable for $st {
559 fn write<W: $crate::util::ser::Writer>(&self, w: &mut W) -> Result<(), $crate::io::Error> {
560 $( self.$field.write(w)?; )*
561 $crate::encode_tlv_stream!(w, {$(($type, self.$tlvfield.as_ref(), $fieldty)),*});
565 impl $crate::util::ser::Readable for $st {
566 fn read<R: $crate::io::Read>(r: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
567 $(let $field = $crate::util::ser::Readable::read(r)?;)*
568 $($crate::_init_tlv_field_var!($tlvfield, $fieldty);)*
569 $crate::decode_tlv_stream!(r, {$(($type, $tlvfield, $fieldty)),*});
579 macro_rules! impl_writeable {
580 ($st:ident, {$($field:ident),*}) => {
581 impl $crate::util::ser::Writeable for $st {
582 fn write<W: $crate::util::ser::Writer>(&self, w: &mut W) -> Result<(), $crate::io::Error> {
583 $( self.$field.write(w)?; )*
588 fn serialized_length(&self) -> usize {
589 let mut len_calc = 0;
590 $( len_calc += self.$field.serialized_length(); )*
595 impl $crate::util::ser::Readable for $st {
596 fn read<R: $crate::io::Read>(r: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
598 $($field: $crate::util::ser::Readable::read(r)?),*
605 /// Write out two bytes to indicate the version of an object.
607 /// $this_version represents a unique version of a type. Incremented whenever the type's
608 /// serialization format has changed or has a new interpretation. Used by a type's reader to
609 /// determine how to interpret fields or if it can understand a serialized object.
611 /// $min_version_that_can_read_this is the minimum reader version which can understand this
612 /// serialized object. Previous versions will simply err with a [`DecodeError::UnknownVersion`].
614 /// Updates to either `$this_version` or `$min_version_that_can_read_this` should be included in
617 /// Both version fields can be specific to this type of object.
619 /// [`DecodeError::UnknownVersion`]: crate::ln::msgs::DecodeError::UnknownVersion
620 macro_rules! write_ver_prefix {
621 ($stream: expr, $this_version: expr, $min_version_that_can_read_this: expr) => {
622 $stream.write_all(&[$this_version; 1])?;
623 $stream.write_all(&[$min_version_that_can_read_this; 1])?;
627 /// Writes out a suffix to an object as a length-prefixed TLV stream which contains potentially
628 /// backwards-compatible, optional fields which old nodes can happily ignore.
630 /// It is written out in TLV format and, as with all TLV fields, unknown even fields cause a
631 /// [`DecodeError::UnknownRequiredFeature`] error, with unknown odd fields ignored.
633 /// This is the preferred method of adding new fields that old nodes can ignore and still function
636 /// [`DecodeError::UnknownRequiredFeature`]: crate::ln::msgs::DecodeError::UnknownRequiredFeature
638 macro_rules! write_tlv_fields {
639 ($stream: expr, {$(($type: expr, $field: expr, $fieldty: tt)),* $(,)*}) => {
640 $crate::_encode_varint_length_prefixed_tlv!($stream, {$(($type, $field, $fieldty)),*})
644 /// Reads a prefix added by [`write_ver_prefix`], above. Takes the current version of the
645 /// serialization logic for this object. This is compared against the
646 /// `$min_version_that_can_read_this` added by [`write_ver_prefix`].
647 macro_rules! read_ver_prefix {
648 ($stream: expr, $this_version: expr) => { {
649 let ver: u8 = Readable::read($stream)?;
650 let min_ver: u8 = Readable::read($stream)?;
651 if min_ver > $this_version {
652 return Err(DecodeError::UnknownVersion);
658 /// Reads a suffix added by [`write_tlv_fields`].
660 /// [`write_tlv_fields`]: crate::write_tlv_fields
662 macro_rules! read_tlv_fields {
663 ($stream: expr, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => { {
664 let tlv_len: $crate::util::ser::BigSize = $crate::util::ser::Readable::read($stream)?;
665 let mut rd = $crate::util::ser::FixedLengthReader::new($stream, tlv_len.0);
666 $crate::decode_tlv_stream!(&mut rd, {$(($type, $field, $fieldty)),*});
667 rd.eat_remaining().map_err(|_| $crate::ln::msgs::DecodeError::ShortRead)?;
671 /// Initializes the struct fields.
673 /// This is exported for use by other exported macros, do not use directly.
676 macro_rules! _init_tlv_based_struct_field {
677 ($field: ident, (default_value, $default: expr)) => {
680 ($field: ident, (static_value, $value: expr)) => {
683 ($field: ident, option) => {
686 ($field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {
687 $crate::_init_tlv_based_struct_field!($field, option)
689 ($field: ident, upgradable_required) => {
692 ($field: ident, upgradable_option) => {
695 ($field: ident, required) => {
698 ($field: ident, required_vec) => {
701 ($field: ident, optional_vec) => {
706 /// Initializes the variable we are going to read the TLV into.
708 /// This is exported for use by other exported macros, do not use directly.
711 macro_rules! _init_tlv_field_var {
712 ($field: ident, (default_value, $default: expr)) => {
713 let mut $field = $crate::util::ser::RequiredWrapper(None);
715 ($field: ident, (static_value, $value: expr)) => {
718 ($field: ident, required) => {
719 let mut $field = $crate::util::ser::RequiredWrapper(None);
721 ($field: ident, (required: $trait: ident $(, $read_arg: expr)?)) => {
722 $crate::_init_tlv_field_var!($field, required);
724 ($field: ident, required_vec) => {
725 let mut $field = Vec::new();
727 ($field: ident, option) => {
728 let mut $field = None;
730 ($field: ident, optional_vec) => {
731 let mut $field = Some(Vec::new());
733 ($field: ident, (option, encoding: ($fieldty: ty, $encoding: ident))) => {
734 $crate::_init_tlv_field_var!($field, option);
736 ($field: ident, (option: $trait: ident $(, $read_arg: expr)?)) => {
737 $crate::_init_tlv_field_var!($field, option);
739 ($field: ident, upgradable_required) => {
740 let mut $field = $crate::util::ser::UpgradableRequired(None);
742 ($field: ident, upgradable_option) => {
743 let mut $field = None;
747 /// Equivalent to running [`_init_tlv_field_var`] then [`read_tlv_fields`].
749 /// This is exported for use by other exported macros, do not use directly.
752 macro_rules! _init_and_read_tlv_fields {
753 ($reader: ident, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => {
755 $crate::_init_tlv_field_var!($field, $fieldty);
758 $crate::read_tlv_fields!($reader, {
759 $(($type, $field, $fieldty)),*
764 /// Implements [`Readable`]/[`Writeable`] for a struct storing it as a set of TLVs
765 /// If `$fieldty` is `required`, then `$field` is a required field that is not an [`Option`] nor a [`Vec`].
766 /// If `$fieldty` is `(default_value, $default)`, then `$field` will be set to `$default` if not present.
767 /// If `$fieldty` is `option`, then `$field` is optional field.
768 /// If `$fieldty` is `optional_vec`, then `$field` is a [`Vec`], which needs to have its individual elements serialized.
769 /// Note that for `optional_vec` no bytes are written if the vec is empty
773 /// # use lightning::impl_writeable_tlv_based;
774 /// struct LightningMessage {
775 /// tlv_integer: u32,
776 /// tlv_default_integer: u32,
777 /// tlv_optional_integer: Option<u32>,
778 /// tlv_vec_type_integer: Vec<u32>,
781 /// impl_writeable_tlv_based!(LightningMessage, {
782 /// (0, tlv_integer, required),
783 /// (1, tlv_default_integer, (default_value, 7)),
784 /// (2, tlv_optional_integer, option),
785 /// (3, tlv_vec_type_integer, optional_vec),
789 /// [`Readable`]: crate::util::ser::Readable
790 /// [`Writeable`]: crate::util::ser::Writeable
792 macro_rules! impl_writeable_tlv_based {
793 ($st: ident, {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}) => {
794 impl $crate::util::ser::Writeable for $st {
795 fn write<W: $crate::util::ser::Writer>(&self, writer: &mut W) -> Result<(), $crate::io::Error> {
796 $crate::write_tlv_fields!(writer, {
797 $(($type, self.$field, $fieldty)),*
803 fn serialized_length(&self) -> usize {
804 use $crate::util::ser::BigSize;
807 let mut len = $crate::util::ser::LengthCalculatingWriter(0);
809 $crate::_get_varint_length_prefixed_tlv_length!(len, $type, self.$field, $fieldty);
813 let mut len_calc = $crate::util::ser::LengthCalculatingWriter(0);
814 BigSize(len as u64).write(&mut len_calc).expect("No in-memory data may fail to serialize");
819 impl $crate::util::ser::Readable for $st {
820 fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
821 $crate::_init_and_read_tlv_fields!(reader, {
822 $(($type, $field, $fieldty)),*
826 $field: $crate::_init_tlv_based_struct_field!($field, $fieldty)
834 /// Defines a struct for a TLV stream and a similar struct using references for non-primitive types,
835 /// implementing [`Readable`] for the former and [`Writeable`] for the latter. Useful as an
836 /// intermediary format when reading or writing a type encoded as a TLV stream. Note that each field
837 /// representing a TLV record has its type wrapped with an [`Option`]. A tuple consisting of a type
838 /// and a serialization wrapper may be given in place of a type when custom serialization is
841 /// [`Readable`]: crate::util::ser::Readable
842 /// [`Writeable`]: crate::util::ser::Writeable
843 macro_rules! tlv_stream {
844 ($name:ident, $nameref:ident, $range:expr, {
845 $(($type:expr, $field:ident : $fieldty:tt)),* $(,)*
848 pub(super) struct $name {
850 pub(super) $field: Option<tlv_record_type!($fieldty)>,
854 #[cfg_attr(test, derive(PartialEq))]
856 pub(super) struct $nameref<'a> {
858 pub(super) $field: Option<tlv_record_ref_type!($fieldty)>,
862 impl<'a> $crate::util::ser::Writeable for $nameref<'a> {
863 fn write<W: $crate::util::ser::Writer>(&self, writer: &mut W) -> Result<(), $crate::io::Error> {
864 encode_tlv_stream!(writer, {
865 $(($type, self.$field, (option, encoding: $fieldty))),*
871 impl $crate::util::ser::SeekReadable for $name {
872 fn read<R: $crate::io::Read + $crate::io::Seek>(reader: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
874 _init_tlv_field_var!($field, option);
876 let rewind = |cursor: &mut R, offset: usize| {
877 cursor.seek($crate::io::SeekFrom::Current(-(offset as i64))).expect("");
879 _decode_tlv_stream_range!(reader, $range, rewind, {
880 $(($type, $field, (option, encoding: $fieldty))),*
893 macro_rules! tlv_record_type {
894 (($type:ty, $wrapper:ident)) => { $type };
895 (($type:ty, $wrapper:ident, $encoder:ty)) => { $type };
896 ($type:ty) => { $type };
899 macro_rules! tlv_record_ref_type {
902 ((u16, $wrapper: ident)) => { u16 };
903 ((u32, $wrapper: ident)) => { u32 };
904 ((u64, $wrapper: ident)) => { u64 };
905 (($type:ty, $wrapper:ident)) => { &'a $type };
906 (($type:ty, $wrapper:ident, $encoder:ty)) => { $encoder };
907 ($type:ty) => { &'a $type };
912 macro_rules! _impl_writeable_tlv_based_enum_common {
913 ($st: ident, $(($variant_id: expr, $variant_name: ident) =>
914 {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
916 $(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*) => {
917 impl $crate::util::ser::Writeable for $st {
918 fn write<W: $crate::util::ser::Writer>(&self, writer: &mut W) -> Result<(), $crate::io::Error> {
920 $($st::$variant_name { $(ref $field),* } => {
921 let id: u8 = $variant_id;
923 $crate::write_tlv_fields!(writer, {
924 $(($type, *$field, $fieldty)),*
927 $($st::$tuple_variant_name (ref field) => {
928 let id: u8 = $tuple_variant_id;
930 field.write(writer)?;
939 /// Implement [`Readable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and tuple
940 /// variants stored directly.
941 /// The format is, for example
943 /// impl_writeable_tlv_based_enum!(EnumName,
944 /// (0, StructVariantA) => {(0, required_variant_field, required), (1, optional_variant_field, option)},
945 /// (1, StructVariantB) => {(0, variant_field_a, required), (1, variant_field_b, required), (2, variant_vec_field, optional_vec)};
946 /// (2, TupleVariantA), (3, TupleVariantB),
949 /// The type is written as a single byte, followed by any variant data.
950 /// Attempts to read an unknown type byte result in [`DecodeError::UnknownRequiredFeature`].
952 /// [`Readable`]: crate::util::ser::Readable
953 /// [`Writeable`]: crate::util::ser::Writeable
954 /// [`DecodeError::UnknownRequiredFeature`]: crate::ln::msgs::DecodeError::UnknownRequiredFeature
956 macro_rules! impl_writeable_tlv_based_enum {
957 ($st: ident, $(($variant_id: expr, $variant_name: ident) =>
958 {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
960 $(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*) => {
961 $crate::_impl_writeable_tlv_based_enum_common!($st,
962 $(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*;
963 $(($tuple_variant_id, $tuple_variant_name)),*);
965 impl $crate::util::ser::Readable for $st {
966 fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Self, $crate::ln::msgs::DecodeError> {
967 let id: u8 = $crate::util::ser::Readable::read(reader)?;
970 // Because read_tlv_fields creates a labeled loop, we cannot call it twice
971 // in the same function body. Instead, we define a closure and call it.
973 $crate::_init_and_read_tlv_fields!(reader, {
974 $(($type, $field, $fieldty)),*
976 Ok($st::$variant_name {
978 $field: $crate::_init_tlv_based_struct_field!($field, $fieldty)
984 $($tuple_variant_id => {
985 Ok($st::$tuple_variant_name(Readable::read(reader)?))
988 Err($crate::ln::msgs::DecodeError::UnknownRequiredFeature)
996 /// Implement [`MaybeReadable`] and [`Writeable`] for an enum, with struct variants stored as TLVs and
997 /// tuple variants stored directly.
999 /// This is largely identical to [`impl_writeable_tlv_based_enum`], except that odd variants will
1000 /// return `Ok(None)` instead of `Err(`[`DecodeError::UnknownRequiredFeature`]`)`. It should generally be preferred
1001 /// when [`MaybeReadable`] is practical instead of just [`Readable`] as it provides an upgrade path for
1002 /// new variants to be added which are simply ignored by existing clients.
1004 /// [`MaybeReadable`]: crate::util::ser::MaybeReadable
1005 /// [`Writeable`]: crate::util::ser::Writeable
1006 /// [`DecodeError::UnknownRequiredFeature`]: crate::ln::msgs::DecodeError::UnknownRequiredFeature
1007 /// [`Readable`]: crate::util::ser::Readable
1009 macro_rules! impl_writeable_tlv_based_enum_upgradable {
1010 ($st: ident, $(($variant_id: expr, $variant_name: ident) =>
1011 {$(($type: expr, $field: ident, $fieldty: tt)),* $(,)*}
1014 $(($tuple_variant_id: expr, $tuple_variant_name: ident)),* $(,)*)*) => {
1015 $crate::_impl_writeable_tlv_based_enum_common!($st,
1016 $(($variant_id, $variant_name) => {$(($type, $field, $fieldty)),*}),*;
1017 $($(($tuple_variant_id, $tuple_variant_name)),*)*);
1019 impl $crate::util::ser::MaybeReadable for $st {
1020 fn read<R: $crate::io::Read>(reader: &mut R) -> Result<Option<Self>, $crate::ln::msgs::DecodeError> {
1021 let id: u8 = $crate::util::ser::Readable::read(reader)?;
1024 // Because read_tlv_fields creates a labeled loop, we cannot call it twice
1025 // in the same function body. Instead, we define a closure and call it.
1027 $crate::_init_and_read_tlv_fields!(reader, {
1028 $(($type, $field, $fieldty)),*
1030 Ok(Some($st::$variant_name {
1032 $field: $crate::_init_tlv_based_struct_field!($field, $fieldty)
1038 $($($tuple_variant_id => {
1039 Ok(Some($st::$tuple_variant_name(Readable::read(reader)?)))
1041 _ if id % 2 == 1 => Ok(None),
1042 _ => Err($crate::ln::msgs::DecodeError::UnknownRequiredFeature),
1051 use crate::io::{self, Cursor};
1052 use crate::prelude::*;
1053 use crate::ln::msgs::DecodeError;
1054 use crate::util::ser::{Writeable, HighZeroBytesDroppedBigSize, VecWriter};
1055 use bitcoin::secp256k1::PublicKey;
1057 // The BOLT TLV test cases don't include any tests which use our "required-value" logic since
1058 // the encoding layer in the BOLTs has no such concept, though it makes our macros easier to
1059 // work with so they're baked into the decoder. Thus, we have a few additional tests below
1060 fn tlv_reader(s: &[u8]) -> Result<(u64, u32, Option<u32>), DecodeError> {
1061 let mut s = Cursor::new(s);
1064 let mut c: Option<u32> = None;
1065 decode_tlv_stream!(&mut s, {(2, a, required), (3, b, required), (4, c, option)});
1070 fn tlv_v_short_read() {
1071 // We only expect a u32 for type 3 (which we are given), but the L says its 8 bytes.
1072 if let Err(DecodeError::ShortRead) = tlv_reader(&::hex::decode(
1073 concat!("0100", "0208deadbeef1badbeef", "0308deadbeef")
1075 } else { panic!(); }
1079 fn tlv_types_out_of_order() {
1080 if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
1081 concat!("0100", "0304deadbeef", "0208deadbeef1badbeef")
1083 } else { panic!(); }
1084 // ...even if its some field we don't understand
1085 if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
1086 concat!("0208deadbeef1badbeef", "0100", "0304deadbeef")
1088 } else { panic!(); }
1092 fn tlv_req_type_missing_or_extra() {
1093 // It's also bad if they included even fields we don't understand
1094 if let Err(DecodeError::UnknownRequiredFeature) = tlv_reader(&::hex::decode(
1095 concat!("0100", "0208deadbeef1badbeef", "0304deadbeef", "0600")
1097 } else { panic!(); }
1098 // ... or if they're missing fields we need
1099 if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
1100 concat!("0100", "0208deadbeef1badbeef")
1102 } else { panic!(); }
1103 // ... even if that field is even
1104 if let Err(DecodeError::InvalidValue) = tlv_reader(&::hex::decode(
1105 concat!("0304deadbeef", "0500")
1107 } else { panic!(); }
1111 fn tlv_simple_good_cases() {
1112 assert_eq!(tlv_reader(&::hex::decode(
1113 concat!("0208deadbeef1badbeef", "03041bad1dea")
1114 ).unwrap()[..]).unwrap(),
1115 (0xdeadbeef1badbeef, 0x1bad1dea, None));
1116 assert_eq!(tlv_reader(&::hex::decode(
1117 concat!("0208deadbeef1badbeef", "03041bad1dea", "040401020304")
1118 ).unwrap()[..]).unwrap(),
1119 (0xdeadbeef1badbeef, 0x1bad1dea, Some(0x01020304)));
1122 #[derive(Debug, PartialEq)]
1123 struct TestUpgradable {
1129 fn upgradable_tlv_reader(s: &[u8]) -> Result<Option<TestUpgradable>, DecodeError> {
1130 let mut s = Cursor::new(s);
1133 let mut c: Option<u32> = None;
1134 decode_tlv_stream!(&mut s, {(2, a, upgradable_required), (3, b, upgradable_required), (4, c, upgradable_option)});
1135 Ok(Some(TestUpgradable { a, b, c, }))
1139 fn upgradable_tlv_simple_good_cases() {
1140 assert_eq!(upgradable_tlv_reader(&::hex::decode(
1141 concat!("0204deadbeef", "03041bad1dea", "0404deadbeef")
1142 ).unwrap()[..]).unwrap(),
1143 Some(TestUpgradable { a: 0xdeadbeef, b: 0x1bad1dea, c: Some(0xdeadbeef) }));
1145 assert_eq!(upgradable_tlv_reader(&::hex::decode(
1146 concat!("0204deadbeef", "03041bad1dea")
1147 ).unwrap()[..]).unwrap(),
1148 Some(TestUpgradable { a: 0xdeadbeef, b: 0x1bad1dea, c: None}));
1152 fn missing_required_upgradable() {
1153 if let Err(DecodeError::InvalidValue) = upgradable_tlv_reader(&::hex::decode(
1154 concat!("0100", "0204deadbeef")
1156 } else { panic!(); }
1157 if let Err(DecodeError::InvalidValue) = upgradable_tlv_reader(&::hex::decode(
1158 concat!("0100", "03041bad1dea")
1160 } else { panic!(); }
1163 // BOLT TLV test cases
1164 fn tlv_reader_n1(s: &[u8]) -> Result<(Option<HighZeroBytesDroppedBigSize<u64>>, Option<u64>, Option<(PublicKey, u64, u64)>, Option<u16>), DecodeError> {
1165 let mut s = Cursor::new(s);
1166 let mut tlv1: Option<HighZeroBytesDroppedBigSize<u64>> = None;
1167 let mut tlv2: Option<u64> = None;
1168 let mut tlv3: Option<(PublicKey, u64, u64)> = None;
1169 let mut tlv4: Option<u16> = None;
1170 decode_tlv_stream!(&mut s, {(1, tlv1, option), (2, tlv2, option), (3, tlv3, option), (254, tlv4, option)});
1171 Ok((tlv1, tlv2, tlv3, tlv4))
1175 fn bolt_tlv_bogus_stream() {
1176 macro_rules! do_test {
1177 ($stream: expr, $reason: ident) => {
1178 if let Err(DecodeError::$reason) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
1179 } else { panic!(); }
1183 // TLVs from the BOLT test cases which should not decode as either n1 or n2
1184 do_test!(concat!("fd01"), ShortRead);
1185 do_test!(concat!("fd0001", "00"), InvalidValue);
1186 do_test!(concat!("fd0101"), ShortRead);
1187 do_test!(concat!("0f", "fd"), ShortRead);
1188 do_test!(concat!("0f", "fd26"), ShortRead);
1189 do_test!(concat!("0f", "fd2602"), ShortRead);
1190 do_test!(concat!("0f", "fd0001", "00"), InvalidValue);
1191 do_test!(concat!("0f", "fd0201", "000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000"), ShortRead);
1193 do_test!(concat!("12", "00"), UnknownRequiredFeature);
1194 do_test!(concat!("fd0102", "00"), UnknownRequiredFeature);
1195 do_test!(concat!("fe01000002", "00"), UnknownRequiredFeature);
1196 do_test!(concat!("ff0100000000000002", "00"), UnknownRequiredFeature);
1200 fn bolt_tlv_bogus_n1_stream() {
1201 macro_rules! do_test {
1202 ($stream: expr, $reason: ident) => {
1203 if let Err(DecodeError::$reason) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
1204 } else { panic!(); }
1208 // TLVs from the BOLT test cases which should not decode as n1
1209 do_test!(concat!("01", "09", "ffffffffffffffffff"), InvalidValue);
1210 do_test!(concat!("01", "01", "00"), InvalidValue);
1211 do_test!(concat!("01", "02", "0001"), InvalidValue);
1212 do_test!(concat!("01", "03", "000100"), InvalidValue);
1213 do_test!(concat!("01", "04", "00010000"), InvalidValue);
1214 do_test!(concat!("01", "05", "0001000000"), InvalidValue);
1215 do_test!(concat!("01", "06", "000100000000"), InvalidValue);
1216 do_test!(concat!("01", "07", "00010000000000"), InvalidValue);
1217 do_test!(concat!("01", "08", "0001000000000000"), InvalidValue);
1218 do_test!(concat!("02", "07", "01010101010101"), ShortRead);
1219 do_test!(concat!("02", "09", "010101010101010101"), InvalidValue);
1220 do_test!(concat!("03", "21", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb"), ShortRead);
1221 do_test!(concat!("03", "29", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb0000000000000001"), ShortRead);
1222 do_test!(concat!("03", "30", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb000000000000000100000000000001"), ShortRead);
1223 do_test!(concat!("03", "31", "043da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb00000000000000010000000000000002"), InvalidValue);
1224 do_test!(concat!("03", "32", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb0000000000000001000000000000000001"), InvalidValue);
1225 do_test!(concat!("fd00fe", "00"), ShortRead);
1226 do_test!(concat!("fd00fe", "01", "01"), ShortRead);
1227 do_test!(concat!("fd00fe", "03", "010101"), InvalidValue);
1228 do_test!(concat!("00", "00"), UnknownRequiredFeature);
1230 do_test!(concat!("02", "08", "0000000000000226", "01", "01", "2a"), InvalidValue);
1231 do_test!(concat!("02", "08", "0000000000000231", "02", "08", "0000000000000451"), InvalidValue);
1232 do_test!(concat!("1f", "00", "0f", "01", "2a"), InvalidValue);
1233 do_test!(concat!("1f", "00", "1f", "01", "2a"), InvalidValue);
1235 // The last BOLT test modified to not require creating a new decoder for one trivial test.
1236 do_test!(concat!("ffffffffffffffffff", "00", "01", "00"), InvalidValue);
1240 fn bolt_tlv_valid_n1_stream() {
1241 macro_rules! do_test {
1242 ($stream: expr, $tlv1: expr, $tlv2: expr, $tlv3: expr, $tlv4: expr) => {
1243 if let Ok((tlv1, tlv2, tlv3, tlv4)) = tlv_reader_n1(&::hex::decode($stream).unwrap()[..]) {
1244 assert_eq!(tlv1.map(|v| v.0), $tlv1);
1245 assert_eq!(tlv2, $tlv2);
1246 assert_eq!(tlv3, $tlv3);
1247 assert_eq!(tlv4, $tlv4);
1248 } else { panic!(); }
1252 do_test!(concat!(""), None, None, None, None);
1253 do_test!(concat!("21", "00"), None, None, None, None);
1254 do_test!(concat!("fd0201", "00"), None, None, None, None);
1255 do_test!(concat!("fd00fd", "00"), None, None, None, None);
1256 do_test!(concat!("fd00ff", "00"), None, None, None, None);
1257 do_test!(concat!("fe02000001", "00"), None, None, None, None);
1258 do_test!(concat!("ff0200000000000001", "00"), None, None, None, None);
1260 do_test!(concat!("01", "00"), Some(0), None, None, None);
1261 do_test!(concat!("01", "01", "01"), Some(1), None, None, None);
1262 do_test!(concat!("01", "02", "0100"), Some(256), None, None, None);
1263 do_test!(concat!("01", "03", "010000"), Some(65536), None, None, None);
1264 do_test!(concat!("01", "04", "01000000"), Some(16777216), None, None, None);
1265 do_test!(concat!("01", "05", "0100000000"), Some(4294967296), None, None, None);
1266 do_test!(concat!("01", "06", "010000000000"), Some(1099511627776), None, None, None);
1267 do_test!(concat!("01", "07", "01000000000000"), Some(281474976710656), None, None, None);
1268 do_test!(concat!("01", "08", "0100000000000000"), Some(72057594037927936), None, None, None);
1269 do_test!(concat!("02", "08", "0000000000000226"), None, Some((0 << 30) | (0 << 5) | (550 << 0)), None, None);
1270 do_test!(concat!("03", "31", "023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb00000000000000010000000000000002"),
1272 PublicKey::from_slice(&::hex::decode("023da092f6980e58d2c037173180e9a465476026ee50f96695963e8efe436f54eb").unwrap()[..]).unwrap(), 1, 2)),
1274 do_test!(concat!("fd00fe", "02", "0226"), None, None, None, Some(550));
1277 fn do_simple_test_tlv_write() -> Result<(), io::Error> {
1278 let mut stream = VecWriter(Vec::new());
1281 _encode_varint_length_prefixed_tlv!(&mut stream, {(1, 1u8, required), (42, None::<u64>, option)});
1282 assert_eq!(stream.0, ::hex::decode("03010101").unwrap());
1285 _encode_varint_length_prefixed_tlv!(&mut stream, {(1, Some(1u8), option)});
1286 assert_eq!(stream.0, ::hex::decode("03010101").unwrap());
1289 _encode_varint_length_prefixed_tlv!(&mut stream, {(4, 0xabcdu16, required), (42, None::<u64>, option)});
1290 assert_eq!(stream.0, ::hex::decode("040402abcd").unwrap());
1293 _encode_varint_length_prefixed_tlv!(&mut stream, {(42, None::<u64>, option), (0xff, 0xabcdu16, required)});
1294 assert_eq!(stream.0, ::hex::decode("06fd00ff02abcd").unwrap());
1297 _encode_varint_length_prefixed_tlv!(&mut stream, {(0, 1u64, required), (42, None::<u64>, option), (0xff, HighZeroBytesDroppedBigSize(0u64), required)});
1298 assert_eq!(stream.0, ::hex::decode("0e00080000000000000001fd00ff00").unwrap());
1301 _encode_varint_length_prefixed_tlv!(&mut stream, {(0, Some(1u64), option), (0xff, HighZeroBytesDroppedBigSize(0u64), required)});
1302 assert_eq!(stream.0, ::hex::decode("0e00080000000000000001fd00ff00").unwrap());
1308 fn simple_test_tlv_write() {
1309 do_simple_test_tlv_write().unwrap();