git.bitcoin.ninja Git - rust-lightning/blob - lightning-invoice/src/ser.rs

   1 use core::fmt;
   2 use core::fmt::{Display, Formatter};
   3 use bech32::{ToBase32, u5, WriteBase32, Base32Len};
   4 use crate::prelude::*;
   5
   6 use super::{Invoice, Sha256, TaggedField, ExpiryTime, MinFinalCltvExpiry, Fallback, PayeePubKey, InvoiceSignature, PositiveTimestamp,
   7         PrivateRoute, Description, RawTaggedField, Currency, RawHrp, SiPrefix, constants, SignedRawInvoice, RawDataPart};
   8
   9 /// Converts a stream of bytes written to it to base32. On finalization the according padding will
  10 /// be applied. That means the results of writing two data blocks with one or two `BytesToBase32`
  11 /// converters will differ.
  12 struct BytesToBase32<'a, W: WriteBase32 + 'a> {
  13         /// Target for writing the resulting `u5`s resulting from the written bytes
  14         writer: &'a mut W,
  15         /// Holds all unwritten bits left over from last round. The bits are stored beginning from
  16         /// the most significant bit. E.g. if buffer_bits=3, then the byte with bits a, b and c will
  17         /// look as follows: [a, b, c, 0, 0, 0, 0, 0]
  18         buffer: u8,
  19         /// Amount of bits left over from last round, stored in buffer.
  20         buffer_bits: u8,
  21 }
  22
  23 impl<'a, W: WriteBase32> BytesToBase32<'a, W> {
  24         /// Create a new bytes-to-base32 converter with `writer` as  a sink for the resulting base32
  25         /// data.
  26         pub fn new(writer: &'a mut W) -> BytesToBase32<'a, W> {
  27                 BytesToBase32 {
  28                         writer,
  29                         buffer: 0,
  30                         buffer_bits: 0,
  31                 }
  32         }
  33
  34         /// Add more bytes to the current conversion unit
  35         pub fn append(&mut self, bytes: &[u8]) -> Result<(), W::Err> {
  36                 for b in bytes {
  37                         self.append_u8(*b)?;
  38                 }
  39                 Ok(())
  40         }
  41
  42         pub fn append_u8(&mut self, byte: u8) -> Result<(), W::Err> {
  43                 // Write first u5 if we have to write two u5s this round. That only happens if the
  44                 // buffer holds too many bits, so we don't have to combine buffer bits with new bits
  45                 // from this rounds byte.
  46                 if self.buffer_bits >= 5 {
  47                         self.writer.write_u5(
  48                                 u5::try_from_u8((self.buffer & 0b11111000) >> 3 ).expect("<32")
  49                         )?;
  50                         self.buffer = self.buffer << 5;
  51                         self.buffer_bits -= 5;
  52                 }
  53
  54                 // Combine all bits from buffer with enough bits from this rounds byte so that they fill
  55                 // a u5. Save reamining bits from byte to buffer.
  56                 let from_buffer = self.buffer >> 3;
  57                 let from_byte = byte >> (3 + self.buffer_bits); // buffer_bits <= 4
  58
  59                 self.writer.write_u5(u5::try_from_u8(from_buffer | from_byte).expect("<32"))?;
  60                 self.buffer = byte << (5 - self.buffer_bits);
  61                 self.buffer_bits = 3 + self.buffer_bits;
  62
  63                 Ok(())
  64         }
  65
  66         pub fn finalize(mut self) ->  Result<(), W::Err> {
  67                 self.inner_finalize()?;
  68                 core::mem::forget(self);
  69                 Ok(())
  70         }
  71
  72         fn inner_finalize(&mut self) -> Result<(), W::Err>{
  73                 // There can be at most two u5s left in the buffer after processing all bytes, write them.
  74                 if self.buffer_bits >= 5 {
  75                         self.writer.write_u5(
  76                                 u5::try_from_u8((self.buffer & 0b11111000) >> 3).expect("<32")
  77                         )?;
  78                         self.buffer = self.buffer << 5;
  79                         self.buffer_bits -= 5;
  80                 }
  81
  82                 if self.buffer_bits != 0 {
  83                         self.writer.write_u5(u5::try_from_u8(self.buffer >> 3).expect("<32"))?;
  84                 }
  85
  86                 Ok(())
  87         }
  88 }
  89
  90 impl<'a, W: WriteBase32> Drop for BytesToBase32<'a, W> {
  91         fn drop(&mut self) {
  92                 self.inner_finalize()
  93                         .expect("Unhandled error when finalizing conversion on drop. User finalize to handle.")
  94         }
  95 }
  96
  97 /// Calculates the base32 encoded size of a byte slice
  98 fn bytes_size_to_base32_size(byte_size: usize) -> usize {
  99         let bits = byte_size * 8;
 100         if bits % 5 == 0 {
 101                 // without padding bits
 102                 bits / 5
 103         } else {
 104                 // with padding bits
 105                 bits / 5 + 1
 106         }
 107 }
 108
 109 impl Display for Invoice {
 110         fn fmt(&self, f: &mut Formatter) -> Result<(), fmt::Error> {
 111                 self.signed_invoice.fmt(f)
 112         }
 113 }
 114
 115 impl Display for SignedRawInvoice {
 116         fn fmt(&self, f: &mut Formatter) -> Result<(), fmt::Error> {
 117                 let hrp = self.raw_invoice.hrp.to_string();
 118                 let mut data  = self.raw_invoice.data.to_base32();
 119                 data.extend_from_slice(&self.signature.to_base32());
 120
 121                 bech32::encode_to_fmt(f, &hrp, data, bech32::Variant::Bech32).expect("HRP is valid")?;
 122
 123                 Ok(())
 124         }
 125 }
 126
 127 /// (C-not exported)
 128 impl Display for RawHrp {
 129         fn fmt(&self, f: &mut Formatter) -> Result<(), fmt::Error> {
 130                 let amount = match self.raw_amount {
 131                         Some(ref amt) => amt.to_string(),
 132                         None => String::new(),
 133                 };
 134
 135                 let si_prefix = match self.si_prefix {
 136                         Some(ref si) => si.to_string(),
 137                         None => String::new(),
 138                 };
 139
 140                 write!(
 141                         f,
 142                         "ln{}{}{}",
 143                         self.currency,
 144                         amount,
 145                         si_prefix
 146                 )
 147         }
 148 }
 149
 150 impl Display for Currency {
 151         fn fmt(&self, f: &mut Formatter) -> Result<(), fmt::Error> {
 152                 let currency_code = match *self {
 153                         Currency::Bitcoin => "bc",
 154                         Currency::BitcoinTestnet => "tb",
 155                         Currency::Regtest => "bcrt",
 156                         Currency::Simnet => "sb",
 157                         Currency::Signet => "tbs",
 158                 };
 159                 write!(f, "{}", currency_code)
 160         }
 161 }
 162
 163 impl Display for SiPrefix {
 164         fn fmt(&self, f: &mut Formatter) -> Result<(), fmt::Error> {
 165                 write!(f, "{}",
 166                         match *self {
 167                                 SiPrefix::Milli => "m",
 168                                 SiPrefix::Micro => "u",
 169                                 SiPrefix::Nano => "n",
 170                                 SiPrefix::Pico => "p",
 171                         }
 172                 )
 173         }
 174 }
 175
 176 fn encode_int_be_base32(int: u64) -> Vec<u5> {
 177         let base = 32u64;
 178
 179         let mut out_vec = Vec::<u5>::new();
 180
 181         let mut rem_int = int;
 182         while rem_int != 0 {
 183                 out_vec.push(u5::try_from_u8((rem_int % base) as u8).expect("always <32"));
 184                 rem_int /= base;
 185         }
 186
 187         out_vec.reverse();
 188         out_vec
 189 }
 190
 191 fn encoded_int_be_base32_size(int: u64) -> usize {
 192         for pos in (0..13).rev() {
 193                 if int & (0x1f << (5 * pos)) != 0 {
 194                         return (pos + 1) as usize;
 195                 }
 196         }
 197         0usize
 198 }
 199
 200 fn encode_int_be_base256<T: Into<u64>>(int: T) -> Vec<u8> {
 201         let base = 256u64;
 202
 203         let mut out_vec = Vec::<u8>::new();
 204
 205         let mut rem_int: u64 = int.into();
 206         while rem_int != 0 {
 207                 out_vec.push((rem_int % base) as u8);
 208                 rem_int /= base;
 209         }
 210
 211         out_vec.reverse();
 212         out_vec
 213 }
 214
 215 /// Appends the default value of `T` to the front of the `in_vec` till it reaches the length
 216 /// `target_length`. If `in_vec` already is too lang `None` is returned.
 217 fn try_stretch<T>(mut in_vec: Vec<T>, target_len: usize) -> Option<Vec<T>>
 218         where T: Default + Copy
 219 {
 220         if in_vec.len() > target_len {
 221                 None
 222         } else if in_vec.len() == target_len {
 223                 Some(in_vec)
 224         } else {
 225                 let mut out_vec = Vec::<T>::with_capacity(target_len);
 226                 out_vec.append(&mut vec![T::default(); target_len - in_vec.len()]);
 227                 out_vec.append(&mut in_vec);
 228                 Some(out_vec)
 229         }
 230 }
 231
 232 impl ToBase32 for RawDataPart {
 233         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 234                 // encode timestamp
 235                 self.timestamp.write_base32(writer)?;
 236
 237                 // encode tagged fields
 238                 for tagged_field in self.tagged_fields.iter() {
 239                         tagged_field.write_base32(writer)?;
 240                 }
 241
 242                 Ok(())
 243         }
 244 }
 245
 246 impl ToBase32 for PositiveTimestamp {
 247         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 248                 // FIXME: use writer for int encoding
 249                 writer.write(
 250                         &try_stretch(encode_int_be_base32(self.as_unix_timestamp()), 7)
 251                                 .expect("Can't be longer due than 7 u5s due to timestamp bounds")
 252                 )
 253         }
 254 }
 255
 256 impl ToBase32 for RawTaggedField {
 257         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 258                 match *self {
 259                         RawTaggedField::UnknownSemantics(ref content) => {
 260                                 writer.write(content)
 261                         },
 262                         RawTaggedField::KnownSemantics(ref tagged_field) => {
 263                                 tagged_field.write_base32(writer)
 264                         }
 265                 }
 266         }
 267 }
 268
 269 impl ToBase32 for Sha256 {
 270         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 271                 (&self.0[..]).write_base32(writer)
 272         }
 273 }
 274 impl Base32Len for Sha256 {
 275         fn base32_len(&self) -> usize {
 276                 (&self.0[..]).base32_len()
 277         }
 278 }
 279
 280 impl ToBase32 for Description {
 281         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 282                 self.as_bytes().write_base32(writer)
 283         }
 284 }
 285
 286 impl Base32Len for Description {
 287         fn base32_len(&self) -> usize {
 288                 self.0.as_bytes().base32_len()
 289         }
 290 }
 291
 292 impl ToBase32 for PayeePubKey {
 293         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 294                 (&self.serialize()[..]).write_base32(writer)
 295         }
 296 }
 297
 298 impl Base32Len for PayeePubKey {
 299         fn base32_len(&self) -> usize {
 300                 bytes_size_to_base32_size(secp256k1::constants::PUBLIC_KEY_SIZE)
 301         }
 302 }
 303
 304 impl ToBase32 for ExpiryTime {
 305         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 306                 writer.write(&encode_int_be_base32(self.as_seconds()))
 307         }
 308 }
 309
 310 impl Base32Len for ExpiryTime {
 311         fn base32_len(&self) -> usize {
 312                 encoded_int_be_base32_size(self.0.as_secs())
 313         }
 314 }
 315
 316 impl ToBase32 for MinFinalCltvExpiry {
 317         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 318                 writer.write(&encode_int_be_base32(self.0))
 319         }
 320 }
 321
 322 impl Base32Len for MinFinalCltvExpiry {
 323         fn base32_len(&self) -> usize {
 324                 encoded_int_be_base32_size(self.0)
 325         }
 326 }
 327
 328 impl ToBase32 for Fallback {
 329         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 330                 match *self {
 331                         Fallback::SegWitProgram {version: v, program: ref p} => {
 332                                 writer.write_u5(v)?;
 333                                 p.write_base32(writer)
 334                         },
 335                         Fallback::PubKeyHash(ref hash) => {
 336                                 writer.write_u5(u5::try_from_u8(17).expect("17 < 32"))?;
 337                                 (&hash[..]).write_base32(writer)
 338                         },
 339                         Fallback::ScriptHash(ref hash) => {
 340                                 writer.write_u5(u5::try_from_u8(18).expect("18 < 32"))?;
 341                                 (&hash[..]).write_base32(writer)
 342                         }
 343                 }
 344         }
 345 }
 346
 347 impl Base32Len for Fallback {
 348         fn base32_len(&self) -> usize {
 349                 match *self {
 350                         Fallback::SegWitProgram {program: ref p, ..} => {
 351                                 bytes_size_to_base32_size(p.len()) + 1
 352                         },
 353                         Fallback::PubKeyHash(_) | Fallback::ScriptHash(_) => {
 354                                 33
 355                         },
 356                 }
 357         }
 358 }
 359
 360 impl ToBase32 for PrivateRoute {
 361         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 362                 let mut converter = BytesToBase32::new(writer);
 363
 364                 for hop in (self.0).0.iter() {
 365                         converter.append(&hop.src_node_id.serialize()[..])?;
 366                         let short_channel_id = try_stretch(
 367                                 encode_int_be_base256(hop.short_channel_id),
 368                                 8
 369                         ).expect("sizeof(u64) == 8");
 370                         converter.append(&short_channel_id)?;
 371
 372                         let fee_base_msat = try_stretch(
 373                                 encode_int_be_base256(hop.fees.base_msat),
 374                                 4
 375                         ).expect("sizeof(u32) == 4");
 376                         converter.append(&fee_base_msat)?;
 377
 378                         let fee_proportional_millionths = try_stretch(
 379                                 encode_int_be_base256(hop.fees.proportional_millionths),
 380                                 4
 381                         ).expect("sizeof(u32) == 4");
 382                         converter.append(&fee_proportional_millionths)?;
 383
 384                         let cltv_expiry_delta = try_stretch(
 385                                 encode_int_be_base256(hop.cltv_expiry_delta),
 386                                 2
 387                         ).expect("sizeof(u16) == 2");
 388                         converter.append(&cltv_expiry_delta)?;
 389                 }
 390
 391                 converter.finalize()?;
 392                 Ok(())
 393         }
 394 }
 395
 396 impl Base32Len for PrivateRoute {
 397         fn base32_len(&self) -> usize {
 398                 bytes_size_to_base32_size((self.0).0.len() * 51)
 399         }
 400 }
 401
 402 impl ToBase32 for TaggedField {
 403         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 404                 /// Writes a tagged field: tag, length and data. `tag` should be in `0..32` otherwise the
 405                 /// function will panic.
 406                 fn write_tagged_field<W, P>(writer: &mut W, tag: u8, payload: &P) -> Result<(), W::Err>
 407                         where W: WriteBase32,
 408                                   P: ToBase32 + Base32Len,
 409                 {
 410                         let len = payload.base32_len();
 411                         assert!(len < 1024, "Every tagged field data can be at most 1023 bytes long.");
 412
 413                         writer.write_u5(u5::try_from_u8(tag).expect("invalid tag, not in 0..32"))?;
 414                         writer.write(&try_stretch(
 415                                 encode_int_be_base32(len as u64),
 416                                 2
 417                         ).expect("Can't be longer than 2, see assert above."))?;
 418                         payload.write_base32(writer)
 419                 }
 420
 421                 match *self {
 422                         TaggedField::PaymentHash(ref hash) => {
 423                                 write_tagged_field(writer, constants::TAG_PAYMENT_HASH, hash)
 424                         },
 425                         TaggedField::Description(ref description) => {
 426                                 write_tagged_field(writer, constants::TAG_DESCRIPTION, description)
 427                         },
 428                         TaggedField::PayeePubKey(ref pub_key) => {
 429                                 write_tagged_field(writer, constants::TAG_PAYEE_PUB_KEY, pub_key)
 430                         },
 431                         TaggedField::DescriptionHash(ref hash) => {
 432                                 write_tagged_field(writer, constants::TAG_DESCRIPTION_HASH, hash)
 433                         },
 434                         TaggedField::ExpiryTime(ref duration) => {
 435                                 write_tagged_field(writer, constants::TAG_EXPIRY_TIME, duration)
 436                         },
 437                         TaggedField::MinFinalCltvExpiry(ref expiry) => {
 438                                 write_tagged_field(writer, constants::TAG_MIN_FINAL_CLTV_EXPIRY, expiry)
 439                         },
 440                         TaggedField::Fallback(ref fallback_address) => {
 441                                 write_tagged_field(writer, constants::TAG_FALLBACK, fallback_address)
 442                         },
 443                         TaggedField::PrivateRoute(ref route_hops) => {
 444                                 write_tagged_field(writer, constants::TAG_PRIVATE_ROUTE, route_hops)
 445                         },
 446                         TaggedField::PaymentSecret(ref payment_secret) => {
 447                                   write_tagged_field(writer, constants::TAG_PAYMENT_SECRET, payment_secret)
 448                         },
 449                         TaggedField::Features(ref features) => {
 450                                 write_tagged_field(writer, constants::TAG_FEATURES, features)
 451                         },
 452                 }
 453         }
 454 }
 455
 456 impl ToBase32 for InvoiceSignature {
 457         fn write_base32<W: WriteBase32>(&self, writer: &mut W) -> Result<(), <W as WriteBase32>::Err> {
 458                 let mut converter = BytesToBase32::new(writer);
 459                 let (recovery_id, signature) = self.0.serialize_compact();
 460                 converter.append(&signature[..])?;
 461                 converter.append_u8(recovery_id.to_i32() as u8)?;
 462                 converter.finalize()
 463         }
 464 }
 465
 466 #[cfg(test)]
 467 mod test {
 468         use bech32::CheckBase32;
 469
 470         #[test]
 471         fn test_currency_code() {
 472                 use Currency;
 473
 474                 assert_eq!("bc", Currency::Bitcoin.to_string());
 475                 assert_eq!("tb", Currency::BitcoinTestnet.to_string());
 476                 assert_eq!("bcrt", Currency::Regtest.to_string());
 477                 assert_eq!("sb", Currency::Simnet.to_string());
 478                 assert_eq!("tbs", Currency::Signet.to_string());
 479         }
 480
 481         #[test]
 482         fn test_raw_hrp() {
 483                 use ::{Currency, RawHrp, SiPrefix};
 484
 485                 let hrp = RawHrp {
 486                         currency: Currency::Bitcoin,
 487                         raw_amount: Some(100),
 488                         si_prefix: Some(SiPrefix::Micro),
 489                 };
 490
 491                 assert_eq!(hrp.to_string(), "lnbc100u");
 492         }
 493
 494         #[test]
 495         fn test_encode_int_be_base32() {
 496                 use ser::encode_int_be_base32;
 497
 498                 let input: u64 = 33764;
 499                 let expected_out = CheckBase32::check_base32(&[1, 0, 31, 4]).unwrap();
 500
 501                 assert_eq!(expected_out, encode_int_be_base32(input));
 502         }
 503
 504         #[test]
 505         fn test_encode_int_be_base256() {
 506                 use ser::encode_int_be_base256;
 507
 508                 let input: u64 = 16842530;
 509                 let expected_out = vec![1, 0, 255, 34];
 510
 511                 assert_eq!(expected_out, encode_int_be_base256(input));
 512         }
 513 }