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#include "funding.h"
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#include <assert.h>
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#include <ccan/mem/mem.h>
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#include <ccan/structeq/structeq.h>
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#include <string.h>
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uint64_t fee_by_feerate(size_t txsize, uint32_t fee_rate)
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{
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/* BOLT #2:
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*
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* The fee for a commitment transaction MUST be calculated by
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* the multiplying this bytescount by the fee rate, dividing
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* by 1000 and truncating (rounding down) the result to an
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* even number of satoshis.
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*/
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return txsize * fee_rate / 2000 * 2;
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}
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static uint64_t calculate_fee_msat(size_t num_nondust_htlcs,
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uint32_t fee_rate)
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{
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uint64_t bytes;
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/* BOLT #2:
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*
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* A node MUST use the formula 338 + 32 bytes for every
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* non-dust HTLC as the bytecount for calculating commitment
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* transaction fees. Note that the fee requirement is
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* unchanged, even if the elimination of dust HTLC outputs has
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* caused a non-zero fee already.
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*/
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bytes = 338 + 32 * num_nondust_htlcs;
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/* milli-satoshis */
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return fee_by_feerate(bytes, fee_rate) * 1000;
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}
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/* Total, in millisatoshi. */
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static uint64_t htlcs_total(const struct channel_htlc *htlcs)
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{
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size_t i, n = tal_count(htlcs);
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uint64_t total = 0;
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for (i = 0; i < n; i++)
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total += htlcs[i].msatoshis;
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return total;
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}
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/* Pay this much fee, if possible. Return amount unpaid. */
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static uint64_t pay_fee(struct channel_oneside *side, uint64_t fee_msat)
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{
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if (side->pay_msat >= fee_msat) {
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side->pay_msat -= fee_msat;
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side->fee_msat += fee_msat;
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return 0;
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} else {
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uint64_t remainder = fee_msat - side->pay_msat;
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side->fee_msat += side->pay_msat;
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side->pay_msat = 0;
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return remainder;
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}
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}
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/* Charge the fee as per BOLT #2 */
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static void recalculate_fees(struct channel_oneside *a,
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struct channel_oneside *b,
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uint64_t fee_msat)
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{
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uint64_t remainder;
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/* Fold in fees, to recalcuate again below. */
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a->pay_msat += a->fee_msat;
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b->pay_msat += b->fee_msat;
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a->fee_msat = b->fee_msat = 0;
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/* BOLT #2:
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*
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* 1. If each nodes can afford half the fee from their
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* to-`final_key` output, reduce the two to-`final_key`
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* outputs accordingly.
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*
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* 2. Otherwise, reduce the to-`final_key` output of one node
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* which cannot afford the fee to zero (resulting in that
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* entire output paying fees). If the remaining
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* to-`final_key` output is greater than the fee remaining,
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* reduce it accordingly, otherwise reduce it to zero to
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* pay as much fee as possible.
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*/
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remainder = pay_fee(a, fee_msat / 2) + pay_fee(b, fee_msat / 2);
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/* If there's anything left, the other side tries to pay for it. */
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remainder = pay_fee(a, remainder);
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pay_fee(b, remainder);
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}
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/* a transfers htlc_msat to a HTLC (gains it, if -ve) */
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static bool change_funding(uint64_t anchor_satoshis,
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uint32_t fee_rate,
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int64_t htlc_msat,
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struct channel_oneside *a,
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struct channel_oneside *b,
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size_t num_nondust_htlcs)
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{
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uint64_t fee_msat;
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assert(a->pay_msat + a->fee_msat
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+ b->pay_msat + b->fee_msat
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+ htlcs_total(a->htlcs) + htlcs_total(b->htlcs)
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== anchor_satoshis * 1000);
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fee_msat = calculate_fee_msat(num_nondust_htlcs, fee_rate);
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/* If A is paying, can it afford it? */
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if (htlc_msat > 0) {
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if (htlc_msat + fee_msat / 2 > a->pay_msat + a->fee_msat)
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return false;
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}
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/* OK, now adjust funds for A, then recalculate fees. */
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a->pay_msat -= htlc_msat;
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recalculate_fees(a, b, fee_msat);
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assert(a->pay_msat + a->fee_msat
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+ b->pay_msat + b->fee_msat
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+ htlcs_total(a->htlcs) + htlcs_total(b->htlcs) + htlc_msat
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== anchor_satoshis * 1000);
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return true;
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}
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struct channel_state *initial_funding(const tal_t *ctx,
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bool am_funder,
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uint64_t anchor_satoshis,
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uint32_t fee_rate)
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{
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uint64_t fee_msat;
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struct channel_state *cstate = talz(ctx, struct channel_state);
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cstate->a.htlcs = tal_arr(cstate, struct channel_htlc, 0);
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cstate->b.htlcs = tal_arr(cstate, struct channel_htlc, 0);
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cstate->fee_rate = fee_rate;
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cstate->anchor = anchor_satoshis;
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/* Anchor must fit in 32 bit. */
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if (anchor_satoshis >= (1ULL << 32) / 1000)
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return tal_free(cstate);
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fee_msat = calculate_fee_msat(0, fee_rate);
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if (fee_msat > anchor_satoshis * 1000)
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return tal_free(cstate);
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/* Initially, all goes back to funder. */
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cstate->a.pay_msat = anchor_satoshis * 1000 - fee_msat;
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cstate->a.fee_msat = fee_msat;
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/* If B (not A) is funder, invert. */
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if (!am_funder)
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invert_cstate(cstate);
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/* Make sure it checks out. */
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assert(change_funding(anchor_satoshis, fee_rate, 0,
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&cstate->a, &cstate->b, 0));
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if (am_funder) {
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assert(cstate->a.fee_msat == fee_msat);
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assert(cstate->b.fee_msat == 0);
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} else {
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assert(cstate->b.fee_msat == fee_msat);
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assert(cstate->a.fee_msat == 0);
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}
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return cstate;
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}
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/* Dust is defined as an output < 546*minRelayTxFee/1000.
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* minRelayTxFee defaults to 1000 satoshi. */
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bool is_dust_amount(uint64_t satoshis)
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{
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return satoshis < 546;
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}
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static size_t count_nondust_htlcs(const struct channel_htlc *htlcs)
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{
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size_t i, n = tal_count(htlcs), nondust = 0;
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for (i = 0; i < n; i++)
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if (!is_dust_amount(htlcs[i].msatoshis / 1000))
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nondust++;
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return nondust;
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}
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static size_t total_nondust_htlcs(const struct channel_state *cstate)
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{
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return count_nondust_htlcs(cstate->a.htlcs)
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+ count_nondust_htlcs(cstate->b.htlcs);
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}
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void adjust_fee(struct channel_state *cstate, uint32_t fee_rate)
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{
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uint64_t fee_msat;
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fee_msat = calculate_fee_msat(total_nondust_htlcs(cstate), fee_rate);
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recalculate_fees(&cstate->a, &cstate->b, fee_msat);
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}
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bool force_fee(struct channel_state *cstate, uint64_t fee)
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{
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/* Beware overflow! */
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if (fee > 0xFFFFFFFFFFFFFFFFULL / 1000)
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return false;
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recalculate_fees(&cstate->a, &cstate->b, fee * 1000);
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return cstate->a.fee_msat + cstate->b.fee_msat == fee * 1000;
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}
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void invert_cstate(struct channel_state *cstate)
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{
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struct channel_oneside tmp;
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tmp = cstate->a;
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cstate->a = cstate->b;
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cstate->b = tmp;
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}
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/* Add a HTLC to @creator if it can afford it. */
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static bool add_htlc(const struct channel_state *cstate,
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struct channel_oneside *creator,
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struct channel_oneside *recipient,
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u32 msatoshis, const struct abs_locktime *expiry,
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const struct sha256 *rhash, uint64_t id)
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{
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size_t n, nondust;
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assert((creator == &cstate->a && recipient == &cstate->b)
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|| (creator == &cstate->b && recipient == &cstate->a));
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/* Remember to count the new one in total txsize if not dust! */
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nondust = total_nondust_htlcs(cstate);
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if (!is_dust_amount(msatoshis / 1000))
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nondust++;
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if (!change_funding(cstate->anchor, cstate->fee_rate,
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msatoshis, creator, recipient, nondust))
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return false;
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n = tal_count(creator->htlcs);
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tal_resize(&creator->htlcs, n+1);
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creator->htlcs[n].msatoshis = msatoshis;
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creator->htlcs[n].expiry = *expiry;
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creator->htlcs[n].rhash = *rhash;
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creator->htlcs[n].id = id;
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memcheck(&creator->htlcs[n].msatoshis,
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sizeof(creator->htlcs[n].msatoshis));
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memcheck(&creator->htlcs[n].rhash, sizeof(creator->htlcs[n].rhash));
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return true;
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}
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/* Remove htlc from creator, credit it to beneficiary. */
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static void remove_htlc(const struct channel_state *cstate,
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struct channel_oneside *creator,
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struct channel_oneside *beneficiary,
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struct channel_oneside *non_beneficiary,
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size_t i)
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{
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size_t n = tal_count(creator->htlcs);
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size_t nondust;
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assert(i < n);
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assert(creator == &cstate->a || creator == &cstate->b);
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assert((beneficiary == &cstate->a && non_beneficiary == &cstate->b)
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|| (beneficiary == &cstate->b && non_beneficiary == &cstate->a));
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/* Remember to remove this one in total txsize if not dust! */
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nondust = total_nondust_htlcs(cstate);
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if (!is_dust_amount(creator->htlcs[i].msatoshis / 1000)) {
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assert(nondust > 0);
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nondust--;
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}
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/* Can't fail since msatoshis is positive. */
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if (!change_funding(cstate->anchor, cstate->fee_rate,
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-(int64_t)creator->htlcs[i].msatoshis,
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beneficiary, non_beneficiary, nondust))
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abort();
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/* Actually remove the HTLC. */
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memmove(creator->htlcs + i, creator->htlcs + i + 1,
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(n - i - 1) * sizeof(*creator->htlcs));
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tal_resize(&creator->htlcs, n-1);
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}
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bool funding_a_add_htlc(struct channel_state *cstate,
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u32 msatoshis, const struct abs_locktime *expiry,
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const struct sha256 *rhash, uint64_t id)
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{
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return add_htlc(cstate, &cstate->a, &cstate->b,
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msatoshis, expiry, rhash, id);
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}
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bool funding_b_add_htlc(struct channel_state *cstate,
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u32 msatoshis, const struct abs_locktime *expiry,
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const struct sha256 *rhash, uint64_t id)
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{
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return add_htlc(cstate, &cstate->b, &cstate->a,
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msatoshis, expiry, rhash, id);
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}
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void funding_a_fail_htlc(struct channel_state *cstate, size_t index)
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{
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remove_htlc(cstate, &cstate->a, &cstate->a, &cstate->b, index);
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}
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void funding_b_fail_htlc(struct channel_state *cstate, size_t index)
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{
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remove_htlc(cstate, &cstate->b, &cstate->b, &cstate->a, index);
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}
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void funding_a_fulfill_htlc(struct channel_state *cstate, size_t index)
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{
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remove_htlc(cstate, &cstate->a, &cstate->b, &cstate->a, index);
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}
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void funding_b_fulfill_htlc(struct channel_state *cstate, size_t index)
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{
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remove_htlc(cstate, &cstate->b, &cstate->a, &cstate->b, index);
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}
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size_t funding_find_htlc(struct channel_oneside *creator,
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const struct sha256 *rhash)
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{
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size_t i;
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for (i = 0; i < tal_count(creator->htlcs); i++) {
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if (structeq(&creator->htlcs[i].rhash, rhash))
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break;
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}
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return i;
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}
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size_t funding_htlc_by_id(struct channel_oneside *creator, uint64_t id)
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{
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size_t i;
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for (i = 0; i < tal_count(creator->htlcs); i++) {
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if (creator->htlcs[i].id == id)
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break;
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}
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return i;
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}
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struct channel_state *copy_funding(const tal_t *ctx,
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const struct channel_state *cstate)
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{
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struct channel_state *cs = tal_dup(ctx, struct channel_state, cstate);
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cs->a.htlcs = tal_dup_arr(cs, struct channel_htlc, cs->a.htlcs,
|
|
|
|
tal_count(cs->a.htlcs), 0);
|
|
|
|
cs->b.htlcs = tal_dup_arr(cs, struct channel_htlc, cs->b.htlcs,
|
|
|
|
tal_count(cs->b.htlcs), 0);
|
|
|
|
return cs;
|
|
|
|
}
|