#include #include #include #include #include #include #include #include #include #ifndef SUPERVERBOSE #define SUPERVERBOSE(...) #endif static bool trim(const struct htlc *htlc, u32 feerate_per_kw, struct amount_sat dust_limit, enum side side) { return htlc_is_trimmed(htlc_owner(htlc), htlc->amount, feerate_per_kw, dust_limit, side); } size_t commit_tx_num_untrimmed(const struct htlc **htlcs, u32 feerate_per_kw, struct amount_sat dust_limit, enum side side) { size_t i, n; for (i = n = 0; i < tal_count(htlcs); i++) n += !trim(htlcs[i], feerate_per_kw, dust_limit, side); return n; } static void add_offered_htlc_out(struct bitcoin_tx *tx, size_t n, const struct htlc *htlc, const struct keyset *keyset) { struct ripemd160 ripemd; u8 *wscript, *p2wsh; struct amount_sat amount = amount_msat_to_sat_round_down(htlc->amount); ripemd160(&ripemd, htlc->rhash.u.u8, sizeof(htlc->rhash.u.u8)); wscript = htlc_offered_wscript(tx, &ripemd, keyset); p2wsh = scriptpubkey_p2wsh(tx, wscript); bitcoin_tx_add_output(tx, p2wsh, &amount); SUPERVERBOSE("# HTLC %" PRIu64 " offered %s wscript %s\n", htlc->id, type_to_string(tmpctx, struct amount_sat, &amount), tal_hex(wscript, wscript)); tal_free(wscript); } static void add_received_htlc_out(struct bitcoin_tx *tx, size_t n, const struct htlc *htlc, const struct keyset *keyset) { struct ripemd160 ripemd; u8 *wscript, *p2wsh; struct amount_sat amount; ripemd160(&ripemd, htlc->rhash.u.u8, sizeof(htlc->rhash.u.u8)); wscript = htlc_received_wscript(tx, &ripemd, &htlc->expiry, keyset); p2wsh = scriptpubkey_p2wsh(tx, wscript); amount = amount_msat_to_sat_round_down(htlc->amount); bitcoin_tx_add_output(tx, p2wsh, &amount); SUPERVERBOSE("# HTLC %"PRIu64" received %s wscript %s\n", htlc->id, type_to_string(tmpctx, struct amount_sat, &amount), tal_hex(wscript, wscript)); tal_free(wscript); } struct bitcoin_tx *commit_tx(const tal_t *ctx, const struct bitcoin_txid *funding_txid, unsigned int funding_txout, struct amount_sat funding, enum side funder, u16 to_self_delay, const struct keyset *keyset, u32 feerate_per_kw, struct amount_sat dust_limit, struct amount_msat self_pay, struct amount_msat other_pay, const struct htlc **htlcs, const struct htlc ***htlcmap, u64 obscured_commitment_number, enum side side) { struct amount_sat base_fee; struct amount_msat total_pay; struct bitcoin_tx *tx; size_t i, n, untrimmed; u32 *cltvs; if (!amount_msat_add(&total_pay, self_pay, other_pay)) abort(); assert(!amount_msat_greater_sat(total_pay, funding)); /* BOLT #3: * * 1. Calculate which committed HTLCs need to be trimmed (see * [Trimmed Outputs](#trimmed-outputs)). */ untrimmed = commit_tx_num_untrimmed(htlcs, feerate_per_kw, dust_limit, side); /* BOLT #3: * * 2. Calculate the base [commitment transaction * fee](#fee-calculation). */ base_fee = commit_tx_base_fee(feerate_per_kw, untrimmed); SUPERVERBOSE("# base commitment transaction fee = %s\n", type_to_string(tmpctx, struct amount_sat, &base_fee)); /* BOLT #3: * * 3. Subtract this base fee from the funder (either `to_local` or * `to_remote`), with a floor of 0 (see [Fee Payment](#fee-payment)). */ try_subtract_fee(funder, side, base_fee, &self_pay, &other_pay); #ifdef PRINT_ACTUAL_FEE { struct amount_sat out = AMOUNT_SAT(0); bool ok = true; for (i = 0; i < tal_count(htlcs); i++) { if (!trim(htlcs[i], feerate_per_kw, dust_limit, side)) ok &= amount_sat_add(&out, out, amount_msat_to_sat_round_down(htlcs[i]->amount)); } if (amount_msat_greater_sat(self_pay, dust_limit)) ok &= amount_sat_add(&out, out, amount_msat_to_sat_round_down(self_pay)); if (amount_msat_greater_sat(other_pay, dust_limit)) ok &= amount_sat_add(&out, out, amount_msat_to_sat_round_down(other_pay)); assert(ok); SUPERVERBOSE("# actual commitment transaction fee = %"PRIu64"\n", funding.satoshis - out.satoshis); /* Raw: test output */ } #endif /* Worst-case sizing: both to-local and to-remote outputs. */ tx = bitcoin_tx(ctx, 1, untrimmed + 2); /* We keep track of which outputs have which HTLCs */ *htlcmap = tal_arr(tx, const struct htlc *, tx->wtx->outputs_allocation_len); /* We keep cltvs for tie-breaking HTLC outputs; we use the same order * for sending the htlc txs, so it may matter. */ cltvs = tal_arr(tmpctx, u32, tx->wtx->outputs_allocation_len); /* This could be done in a single loop, but we follow the BOLT * literally to make comments in test vectors clearer. */ n = 0; /* BOLT #3: * * 3. For every offered HTLC, if it is not trimmed, add an * [offered HTLC output](#offered-htlc-outputs). */ for (i = 0; i < tal_count(htlcs); i++) { if (htlc_owner(htlcs[i]) != side) continue; if (trim(htlcs[i], feerate_per_kw, dust_limit, side)) continue; add_offered_htlc_out(tx, n, htlcs[i], keyset); (*htlcmap)[n] = htlcs[i]; cltvs[n] = abs_locktime_to_blocks(&htlcs[i]->expiry); n++; } /* BOLT #3: * * 4. For every received HTLC, if it is not trimmed, add an * [received HTLC output](#received-htlc-outputs). */ for (i = 0; i < tal_count(htlcs); i++) { if (htlc_owner(htlcs[i]) == side) continue; if (trim(htlcs[i], feerate_per_kw, dust_limit, side)) continue; add_received_htlc_out(tx, n, htlcs[i], keyset); (*htlcmap)[n] = htlcs[i]; cltvs[n] = abs_locktime_to_blocks(&htlcs[i]->expiry); n++; } /* BOLT #3: * * 5. If the `to_local` amount is greater or equal to * `dust_limit_satoshis`, add a [`to_local` * output](#to_local-output). */ if (amount_msat_greater_eq_sat(self_pay, dust_limit)) { u8 *wscript = to_self_wscript(tmpctx, to_self_delay,keyset); u8 *p2wsh = scriptpubkey_p2wsh(tx, wscript); struct amount_sat amount = amount_msat_to_sat_round_down(self_pay); bitcoin_tx_add_output(tx, p2wsh, &amount); (*htlcmap)[n] = NULL; /* We don't assign cltvs[n]: if we use it, order doesn't matter. * However, valgrind will warn us something wierd is happening */ SUPERVERBOSE("# to-local amount %s wscript %s\n", type_to_string(tmpctx, struct amount_sat, &amount), tal_hex(tmpctx, wscript)); n++; } /* BOLT #3: * * 6. If the `to_remote` amount is greater or equal to * `dust_limit_satoshis`, add a [`to_remote` * output](#to_remote-output). */ if (amount_msat_greater_eq_sat(other_pay, dust_limit)) { struct amount_sat amount = amount_msat_to_sat_round_down(other_pay); u8 *p2wpkh = scriptpubkey_p2wpkh(tx, &keyset->other_payment_key); /* BOLT #3: * * #### `to_remote` Output * * This output sends funds to the other peer and thus is a simple * P2WPKH to `remotepubkey`. */ int pos = bitcoin_tx_add_output(tx, p2wpkh, &amount); assert(pos == n); (*htlcmap)[n] = NULL; /* We don't assign cltvs[n]: if we use it, order doesn't matter. * However, valgrind will warn us something wierd is happening */ SUPERVERBOSE("# to-remote amount %s P2WPKH(%s)\n", type_to_string(tmpctx, struct amount_sat, &amount), type_to_string(tmpctx, struct pubkey, &keyset->other_payment_key)); n++; } /* BOLT #2: * * - MUST set `channel_reserve_satoshis` greater than or equal to * `dust_limit_satoshis`. */ /* This means there must be at least one output. */ assert(n > 0); assert(n <= tx->wtx->outputs_allocation_len); tal_resize(htlcmap, n); /* BOLT #3: * * 7. Sort the outputs into [BIP 69+CLTV * order](#transaction-input-and-output-ordering) */ permute_outputs(tx, cltvs, (const void **)*htlcmap); /* BOLT #3: * * ## Commitment Transaction * * * version: 2 */ assert(tx->wtx->version == 2); /* BOLT #3: * * * locktime: upper 8 bits are 0x20, lower 24 bits are the lower 24 bits of the obscured commitment number */ tx->wtx->locktime = (0x20000000 | (obscured_commitment_number & 0xFFFFFF)); /* BOLT #3: * * * txin count: 1 * * `txin[0]` outpoint: `txid` and `output_index` from * `funding_created` message */ /* BOLT #3: * * * `txin[0]` sequence: upper 8 bits are 0x80, lower 24 bits are upper 24 bits of the obscured commitment number */ u32 sequence = (0x80000000 | ((obscured_commitment_number>>24) & 0xFFFFFF)); bitcoin_tx_add_input(tx, funding_txid, funding_txout, sequence, &funding, NULL); return tx; }