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391da2f440
This is the simple version which always tries to keep some sats if we have an anchor channel. Turns out that we need something more sophisticated for multifundchannel, so that's next. Signed-off-by: Rusty Russell <rusty@rustcorp.com.au> Changelog-Changed: JSON-RPC: `withdraw` will refuse to spend funds below `min-emergency-msat` if we have any anchor channels (and `all` will be reduced appropriately). Changelog-Changed: JSON-RPC: `fundpsbt` and `utxopsbt` will refuse to spend funds below `min-emergency-msat` if we have any anchor channels.
346 lines
12 KiB
C
346 lines
12 KiB
C
#ifndef LIGHTNING_BITCOIN_TX_H
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#define LIGHTNING_BITCOIN_TX_H
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#include "config.h"
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#include <bitcoin/chainparams.h>
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#include <bitcoin/shadouble.h>
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#include <bitcoin/signature.h>
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#include <bitcoin/varint.h>
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#include <ccan/structeq/structeq.h>
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#include <common/amount.h>
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#include <wally_transaction.h>
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#define BITCOIN_TX_DEFAULT_SEQUENCE 0xFFFFFFFF
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/* BIP 125: Any nsequence < 0xFFFFFFFE is replacable.
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* And bitcoind uses this value. */
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#define BITCOIN_TX_RBF_SEQUENCE 0xFFFFFFFD
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struct wally_psbt;
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struct bitcoin_txid {
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struct sha256_double shad;
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};
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struct bitcoin_outpoint {
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struct bitcoin_txid txid;
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u32 n;
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};
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/* Define bitcoin_txid_eq */
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STRUCTEQ_DEF(bitcoin_txid, 0, shad.sha.u);
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/* Define bitcoin_outpoint_eq */
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STRUCTEQ_DEF(bitcoin_outpoint, 0, txid.shad.sha.u, n);
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struct bitcoin_tx {
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struct wally_tx *wtx;
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/* Keep a reference to the ruleset we have to abide by */
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const struct chainparams *chainparams;
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/* psbt struct */
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struct wally_psbt *psbt;
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};
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struct bitcoin_tx_output {
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struct amount_sat amount;
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u8 *script;
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};
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struct bitcoin_tx_output *new_tx_output(const tal_t *ctx,
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struct amount_sat amount,
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const u8 *script);
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/* SHA256^2 the tx in legacy format. */
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void bitcoin_txid(const struct bitcoin_tx *tx, struct bitcoin_txid *txid);
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void wally_txid(const struct wally_tx *wtx, struct bitcoin_txid *txid);
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/* Linear bytes of tx. */
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u8 *linearize_tx(const tal_t *ctx, const struct bitcoin_tx *tx);
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u8 *linearize_wtx(const tal_t *ctx, const struct wally_tx *wtx);
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/* Get weight of tx in Sipa; assumes it will have witnesses! */
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size_t bitcoin_tx_weight(const struct bitcoin_tx *tx);
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size_t wally_tx_weight(const struct wally_tx *wtx);
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/* Allocate a tx: you just need to fill in inputs and outputs (they're
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* zeroed with inputs' sequence_number set to FFFFFFFF) */
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struct bitcoin_tx *bitcoin_tx(const tal_t *ctx,
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const struct chainparams *chainparams,
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varint_t input_count, varint_t output_count,
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u32 nlocktime);
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/* Make a (deep) copy */
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struct bitcoin_tx *clone_bitcoin_tx(const tal_t *ctx,
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const struct bitcoin_tx *tx TAKES);
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/* This takes a raw bitcoin tx in hex. */
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struct bitcoin_tx *bitcoin_tx_from_hex(const tal_t *ctx, const char *hex,
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size_t hexlen);
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/* Parse hex string to get txid (reversed, a-la bitcoind). */
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bool bitcoin_txid_from_hex(const char *hexstr, size_t hexstr_len,
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struct bitcoin_txid *txid);
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/* Get hex string of txid (reversed, a-la bitcoind). */
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bool bitcoin_txid_to_hex(const struct bitcoin_txid *txid,
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char *hexstr, size_t hexstr_len);
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/* Create a bitcoin_tx from a psbt */
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struct bitcoin_tx *bitcoin_tx_with_psbt(const tal_t *ctx, struct wally_psbt *psbt);
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/* Internal de-linearization functions. */
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struct bitcoin_tx *pull_bitcoin_tx(const tal_t *ctx,
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const u8 **cursor, size_t *max);
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/* Helper to create a wally_tx_output: make sure to wally_tx_output_free!
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* Returns NULL if amount is extreme (wally doesn't like).
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*/
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struct wally_tx_output *wally_tx_output(const tal_t *ctx,
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const u8 *script,
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struct amount_sat amount);
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/* Add one output to tx. */
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int bitcoin_tx_add_output(struct bitcoin_tx *tx, const u8 *script,
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const u8 *wscript,
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struct amount_sat amount);
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/* Remove one output. */
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void bitcoin_tx_remove_output(struct bitcoin_tx *tx, size_t outnum);
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/* Set the locktime for a transaction */
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void bitcoin_tx_set_locktime(struct bitcoin_tx *tx, u32 locktime);
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/* Add a new input to a bitcoin tx.
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*
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* For P2WSH inputs, we'll also store the wscript and/or scriptPubkey
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* Passing in just the {input_wscript}, we'll generate the scriptPubkey for you.
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* In some cases we may not have the wscript, in which case the scriptPubkey
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* should be provided. We'll check that it's P2WSH before saving it */
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int bitcoin_tx_add_input(struct bitcoin_tx *tx,
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const struct bitcoin_outpoint *outpoint,
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u32 sequence, const u8 *scriptSig,
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struct amount_sat amount, const u8 *scriptPubkey,
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const u8 *input_wscript);
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/* This is useful because wally uses a raw byte array for txids */
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bool wally_tx_input_spends(const struct wally_tx_input *input,
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const struct bitcoin_outpoint *outpoint);
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struct amount_asset
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wally_tx_output_get_amount(const struct wally_tx_output *output);
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/**
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* Set the output amount on the transaction.
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*
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* Allows changing the amount on the transaction output after it was set on
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* creation. This is useful to grind a feerate or subtract the fee from an
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* existing output.
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*/
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void bitcoin_tx_output_set_amount(struct bitcoin_tx *tx, int outnum,
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struct amount_sat amount);
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/**
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* Helper to get the script of a script's output as a tal_arr
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*
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* Internally we use a `wally_tx` to represent the transaction. The script
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* attached to a `wally_tx_output` is not a `tal_arr`, so in order to keep the
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* comfort of being able to call `tal_bytelen` and similar on a script we just
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* return a `tal_arr` clone of the original script.
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*/
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const u8 *bitcoin_tx_output_get_script(const tal_t *ctx, const struct bitcoin_tx *tx, int outnum);
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/**
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* Helper to get the script of a script's output as a tal_arr
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*
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* The script attached to a `wally_tx_output` is not a `tal_arr`, so in order to keep the
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* comfort of being able to call `tal_bytelen` and similar on a script we just
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* return a `tal_arr` clone of the original script.
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*/
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const u8 *wally_tx_output_get_script(const tal_t *ctx,
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const struct wally_tx_output *output);
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/**
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* Helper to get a witness script for an output.
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*/
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u8 *bitcoin_tx_output_get_witscript(const tal_t *ctx, const struct bitcoin_tx *tx, int outnum);
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/** bitcoin_tx_output_get_amount_sat - Helper to get transaction output's amount
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*
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* Internally we use a `wally_tx` to represent the transaction. The
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* satoshi amount isn't a struct amount_sat, so we need a conversion
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*/
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void bitcoin_tx_output_get_amount_sat(const struct bitcoin_tx *tx, int outnum,
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struct amount_sat *amount);
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/**
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* Helper to just get an amount_sat for the output amount.
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*/
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struct amount_asset bitcoin_tx_output_get_amount(const struct bitcoin_tx *tx,
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int outnum);
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/**
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* Set the input witness.
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*
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* Given that we generate the witness after constructing the transaction
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* itself, we need a way to attach a witness to an existing input.
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*/
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void bitcoin_tx_input_set_witness(struct bitcoin_tx *tx, int innum,
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u8 **witness TAKES);
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/**
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* Set the input script on the given input.
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*/
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void bitcoin_tx_input_set_script(struct bitcoin_tx *tx, int innum, u8 *script);
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/**
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* Wrap the raw txhash in the wally_tx_input into a bitcoin_txid
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*/
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void bitcoin_tx_input_get_outpoint(const struct bitcoin_tx *tx,
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int innum,
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struct bitcoin_outpoint *outpoint);
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void bitcoin_tx_input_get_txid(const struct bitcoin_tx *tx, int innum,
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struct bitcoin_txid *out);
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void wally_tx_input_get_txid(const struct wally_tx_input *in,
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struct bitcoin_txid *txid);
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void wally_tx_input_get_outpoint(const struct wally_tx_input *in,
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struct bitcoin_outpoint *outpoint);
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/**
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* Overwrite the txhash and index in the wally_tx_input
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*/
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void bitcoin_tx_input_set_outpoint(struct bitcoin_tx *tx, int innum,
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const struct bitcoin_outpoint *outpoint);
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/**
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* Check a transaction for consistency.
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*
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* Mainly for the transition from `bitcoin_tx` to the `wally_tx`. Checks that
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* both transactions serialize to two identical representations.
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*/
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bool bitcoin_tx_check(const struct bitcoin_tx *tx);
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/**
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* Finalize a transaction by truncating overallocated and temporary
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* fields. This includes adding a fee output for elements transactions or
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* adjusting an existing fee output, and resizing metadata arrays for inputs
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* and outputs.
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*/
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void bitcoin_tx_finalize(struct bitcoin_tx *tx);
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/**
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* Returns true if the given outnum is a fee output
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*/
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bool elements_wtx_output_is_fee(const struct wally_tx *tx, int outnum);
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/**
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* Returns true if the given outnum is a fee output
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*/
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bool elements_tx_output_is_fee(const struct bitcoin_tx *tx, int outnum);
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/** Attempt to compute the elements overhead given a base bitcoin size.
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*
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* The overhead consists of 2 empty proofs for the transaction, 6 bytes of
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* proofs per input and 35 bytes per output. In addition the explicit fee
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* output will add 9 bytes and the per output overhead as well.
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*/
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static inline size_t elements_tx_overhead(const struct chainparams *chainparams,
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size_t incount, size_t outcount)
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{
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size_t overhead;
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if (!chainparams->is_elements)
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return 0;
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/* Each transaction has surjection and rangeproof (both empty
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* for us as long as we use unblinded L-BTC transactions). */
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overhead = 2 * 4;
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/* For elements we also need to add the fee output and the
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* overhead for rangeproofs into the mix. */
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overhead += (8 + 1) * 4; /* Bitcoin style output */
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/* All outputs have a bit of elements overhead (incl fee) */
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overhead += (32 + 1 + 1 + 1) * 4 * (outcount + 1); /* Elements added fields */
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/* Inputs have 6 bytes of blank proofs attached. */
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overhead += 6 * incount;
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return overhead;
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}
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/**
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* Calculate the fees for this transaction
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*/
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struct amount_sat bitcoin_tx_compute_fee(const struct bitcoin_tx *tx);
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/**
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* Calculate the feerate for this transaction (in perkw)
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*/
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u32 tx_feerate(const struct bitcoin_tx *tx);
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/*
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* Calculate the fees for this transaction, given a pre-computed input balance.
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*
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* This is needed for cases where the transaction's psbt metadata isn't properly filled
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* in typically due to being instantiated from a tx hex (i.e. from a block scan)
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*/
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struct amount_sat bitcoin_tx_compute_fee_w_inputs(const struct bitcoin_tx *tx,
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struct amount_sat input_val);
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/* Wire marshalling and unmarshalling */
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void fromwire_bitcoin_txid(const u8 **cursor, size_t *max,
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struct bitcoin_txid *txid);
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struct bitcoin_tx *fromwire_bitcoin_tx(const tal_t *ctx,
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const u8 **cursor, size_t *max);
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void towire_bitcoin_txid(u8 **pptr, const struct bitcoin_txid *txid);
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void towire_bitcoin_tx(u8 **pptr, const struct bitcoin_tx *tx);
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void towire_bitcoin_outpoint(u8 **pptr, const struct bitcoin_outpoint *outp);
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void fromwire_bitcoin_outpoint(const u8 **cursor, size_t *max,
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struct bitcoin_outpoint *outp);
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char *fmt_bitcoin_tx(const tal_t *ctx, const struct bitcoin_tx *tx);
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/* Various weights of transaction parts. */
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size_t bitcoin_tx_core_weight(size_t num_inputs, size_t num_outputs);
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size_t bitcoin_tx_output_weight(size_t outscript_len);
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/* Weight to push sig on stack. */
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size_t bitcoin_tx_input_sig_weight(void);
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/* Segwit input, but with parameter for witness weight (size) */
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size_t bitcoin_tx_input_weight(bool p2sh, size_t witness_weight);
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/* The witness weight for a simple (sig + key) input */
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size_t bitcoin_tx_simple_input_witness_weight(void);
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/* We only do segwit inputs, and we assume witness is sig + key */
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size_t bitcoin_tx_simple_input_weight(bool p2sh);
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/* The witness for our 2of2 input (closing or commitment tx). */
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size_t bitcoin_tx_2of2_input_witness_weight(void);
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/**
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* change_fee - what's the cost to add a change output to this tx?
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* @feerate_perkw: feerate.
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* @total_weight: current weight of tx.
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*
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* We pass in the total_weight of the tx (up until this point) so as
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* to avoid any off-by-one errors with rounding the change fee (down)
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*/
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struct amount_sat change_fee(u32 feerate_perkw, size_t total_weight);
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/**
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* change_amount - Is it worth making a P2WPKH change output at this feerate?
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* @excess: input amount we have above the tx fee and other outputs.
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* @feerate_perkw: feerate.
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* @total_weight: current weight of tx.
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*
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* If it's not worth (or possible) to make change, returns AMOUNT_SAT(0).
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* Otherwise returns the amount of the change output to add (@excess minus
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* the change_fee()).
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*/
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struct amount_sat change_amount(struct amount_sat excess, u32 feerate_perkw,
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size_t total_weight);
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#endif /* LIGHTNING_BITCOIN_TX_H */
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