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522 lines
14 KiB
522 lines
14 KiB
#include <assert.h>
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#include <bitcoin/block.h>
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#include <bitcoin/pullpush.h>
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#include <bitcoin/tx.h>
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#include <ccan/cast/cast.h>
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#include <ccan/crypto/sha256/sha256.h>
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#include <ccan/endian/endian.h>
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#include <ccan/mem/mem.h>
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#include <ccan/read_write_all/read_write_all.h>
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#include <ccan/str/hex/hex.h>
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#include <common/type_to_string.h>
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#include <stdio.h>
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#include <wire/wire.h>
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#define SEGREGATED_WITNESS_FLAG 0x1
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int bitcoin_tx_add_output(struct bitcoin_tx *tx, const u8 *script,
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struct amount_sat amount)
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{
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size_t i = tx->wtx->num_outputs;
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struct wally_tx_output *output;
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int ret;
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u64 satoshis = amount.satoshis; /* Raw: low-level helper */
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const struct chainparams *chainparams = tx->chainparams;
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assert(i < tx->wtx->outputs_allocation_len);
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assert(tx->wtx != NULL);
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assert(chainparams);
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if (chainparams->is_elements) {
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u8 value[9];
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ret = wally_tx_confidential_value_from_satoshi(satoshis, value,
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sizeof(value));
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assert(ret == WALLY_OK);
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ret = wally_tx_elements_output_init_alloc(
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script, tal_bytelen(script), chainparams->fee_asset_tag, 33,
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value, sizeof(value), NULL, 0, NULL, 0, NULL, 0, &output);
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assert(ret == WALLY_OK);
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/* Cheat a bit by also setting the numeric satoshi value,
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* otherwise we end up converting a number of times */
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output->satoshi = satoshis;
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} else {
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ret = wally_tx_output_init_alloc(satoshis, script,
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tal_bytelen(script), &output);
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assert(ret == WALLY_OK);
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}
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ret = wally_tx_add_output(tx->wtx, output);
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assert(ret == WALLY_OK);
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wally_tx_output_free(output);
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bitcoin_tx_output_set_amount(tx, i, amount);
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return i;
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}
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int bitcoin_tx_add_multi_outputs(struct bitcoin_tx *tx,
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struct bitcoin_tx_output **outputs)
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{
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for (size_t j = 0; j < tal_count(outputs); j++)
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bitcoin_tx_add_output(tx, outputs[j]->script,
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outputs[j]->amount);
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return tx->wtx->num_outputs;
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}
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static bool elements_tx_output_is_fee(const struct bitcoin_tx *tx, int outnum)
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{
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assert(outnum < tx->wtx->num_outputs);
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return chainparams->is_elements &&
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tx->wtx->outputs[outnum].script_len == 0;
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}
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/**
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* Compute how much fee we are actually sending with this transaction.
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*/
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static struct amount_sat bitcoin_tx_compute_fee(const struct bitcoin_tx *tx)
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{
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struct amount_sat fee = AMOUNT_SAT(0), value;
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struct amount_asset asset;
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bool ok;
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for (size_t i = 0; i < tal_count(tx->input_amounts); i++) {
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value.satoshis = tx->input_amounts[i]->satoshis; /* Raw: fee computation */
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ok = amount_sat_add(&fee, fee, value);
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assert(ok);
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}
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for (size_t i = 0; i < tx->wtx->num_outputs; i++) {
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asset = bitcoin_tx_output_get_amount(tx, i);
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if (elements_tx_output_is_fee(tx, i) ||
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!amount_asset_is_main(&asset))
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continue;
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value = amount_asset_to_sat(&asset);
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ok = amount_sat_sub(&fee, fee, value);
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assert(ok);
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}
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return fee;
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}
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int elements_tx_add_fee_output(struct bitcoin_tx *tx)
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{
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struct amount_sat fee = bitcoin_tx_compute_fee(tx);
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int pos = -1;
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/* If we aren't using elements, we don't add explicit fee outputs */
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if (!chainparams->is_elements || amount_sat_eq(fee, AMOUNT_SAT(0)))
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return -1;
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/* Try to find any existing fee output */
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for (int i=0; i<tx->wtx->num_outputs; i++) {
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if (elements_tx_output_is_fee(tx, i)) {
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assert(pos == -1);
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pos = i;
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}
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}
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if (pos == -1) {
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return bitcoin_tx_add_output(tx, NULL, fee);
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} else {
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bitcoin_tx_output_set_amount(tx, pos, fee);
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return pos;
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}
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}
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int bitcoin_tx_add_input(struct bitcoin_tx *tx, const struct bitcoin_txid *txid,
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u32 outnum, u32 sequence,
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struct amount_sat amount, u8 *script)
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{
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struct wally_tx_input *input;
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size_t i;
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assert(tx->wtx != NULL);
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i = tx->wtx->num_inputs;
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wally_tx_input_init_alloc(txid->shad.sha.u.u8,
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sizeof(struct bitcoin_txid), outnum, sequence,
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script, tal_bytelen(script),
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NULL /* Empty witness stack */, &input);
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input->features = chainparams->is_elements ? WALLY_TX_IS_ELEMENTS : 0;
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wally_tx_add_input(tx->wtx, input);
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wally_tx_input_free(input);
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/* Now store the input amount if we know it, so we can sign later */
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if (tal_count(tx->input_amounts) < tx->wtx->num_inputs)
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tal_resize(&tx->input_amounts, tx->wtx->num_inputs);
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tx->input_amounts[i] = tal_free(tx->input_amounts[i]);
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tx->input_amounts[i] = tal_dup(tx, struct amount_sat, &amount);
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return i;
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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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u8 *newtx;
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size_t written;
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int flags = WALLY_TX_FLAG_USE_WITNESS;
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if (wally_tx_get_length(tx->wtx, flags, &written) != WALLY_OK)
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return false;
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newtx = tal_arr(tmpctx, u8, written);
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if (wally_tx_to_bytes(tx->wtx, flags, newtx, written, &written) !=
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WALLY_OK)
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return false;
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if (written != tal_bytelen(newtx))
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return false;
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return true;
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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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u64 satoshis = amount.satoshis; /* Raw: low-level helper */
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struct wally_tx_output *output = &tx->wtx->outputs[outnum];
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assert(outnum < tx->wtx->num_outputs);
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if (chainparams->is_elements) {
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int ret = wally_tx_confidential_value_from_satoshi(
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satoshis, output->value, output->value_len);
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assert(ret == WALLY_OK);
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} else {
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output->satoshi = satoshis;
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}
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}
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const u8 *bitcoin_tx_output_get_script(const tal_t *ctx,
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const struct bitcoin_tx *tx, int outnum)
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{
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const struct wally_tx_output *output;
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u8 *res;
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assert(outnum < tx->wtx->num_outputs);
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output = &tx->wtx->outputs[outnum];
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if (output->script == NULL) {
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/* This can happen for coinbase transactions and pegin
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* transactions */
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return NULL;
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}
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res = tal_arr(ctx, u8, output->script_len);
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memcpy(res, output->script, output->script_len);
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return res;
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}
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/* FIXME(cdecker) Make the caller pass in a reference to amount_asset, and
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* return false if unintelligible/encrypted. (WARN UNUSED). */
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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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struct amount_asset amount;
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struct wally_tx_output *output;
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be64 raw;
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assert(tx->chainparams);
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assert(outnum < tx->wtx->num_outputs);
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output = &tx->wtx->outputs[outnum];
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if (chainparams->is_elements) {
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assert(output->asset_len == sizeof(amount.asset));
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memcpy(&amount.asset, output->asset, sizeof(amount.asset));
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/* We currently only support explicit value asset tags, others
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* are confidential, so don't even try to assign a value to
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* it. */
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if (output->asset[0] == 0x01) {
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memcpy(&raw, output->value + 1, sizeof(raw));
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amount.value = be64_to_cpu(raw);
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} else {
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amount.value = 0;
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}
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} else {
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/* Do not assign amount.asset, we should never touch it in
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* non-elements scenarios. */
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amount.value = tx->wtx->outputs[outnum].satoshi;
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}
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return amount;
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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)
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{
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struct wally_tx_witness_stack *stack = NULL;
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size_t stack_size = tal_count(witness);
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/* Free any lingering witness */
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if (witness) {
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wally_tx_witness_stack_init_alloc(stack_size, &stack);
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for (size_t i = 0; i < stack_size; i++)
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wally_tx_witness_stack_add(stack, witness[i],
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tal_bytelen(witness[i]));
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}
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wally_tx_set_input_witness(tx->wtx, innum, stack);
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if (stack)
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wally_tx_witness_stack_free(stack);
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if (taken(witness))
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tal_free(witness);
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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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wally_tx_set_input_script(tx->wtx, innum, script, tal_bytelen(script));
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}
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const u8 *bitcoin_tx_input_get_witness(const tal_t *ctx,
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const struct bitcoin_tx *tx, int innum,
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int witnum)
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{
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const u8 *witness_item;
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struct wally_tx_witness_item *item;
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assert(innum < tx->wtx->num_inputs);
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assert(witnum < tx->wtx->inputs[innum].witness->num_items);
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item = &tx->wtx->inputs[innum].witness->items[witnum];
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witness_item =
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tal_dup_arr(ctx, u8, item->witness, item->witness_len, 0);
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return witness_item;
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}
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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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{
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assert(innum < tx->wtx->num_inputs);
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assert(sizeof(struct bitcoin_txid) ==
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sizeof(tx->wtx->inputs[innum].txhash));
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memcpy(out, tx->wtx->inputs[innum].txhash, sizeof(struct bitcoin_txid));
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}
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/* BIP144:
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* If the witness is empty, the old serialization format should be used. */
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static bool uses_witness(const struct bitcoin_tx *tx)
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{
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size_t i;
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for (i = 0; i < tx->wtx->num_inputs; i++) {
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if (tx->wtx->inputs[i].witness)
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return true;
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}
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return false;
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}
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/* For signing, we ignore input scripts on other inputs, and pretend
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* the current input has a certain script: this is indicated by a
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* non-NULL override_script.
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*
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* For this (and other signing weirdness like SIGHASH_SINGLE), we
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* also need the current input being signed; that's in input_num.
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* We also need sighash_type.
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*/
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static void push_tx(const struct bitcoin_tx *tx,
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const u8 *override_script,
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size_t input_num,
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void (*push)(const void *, size_t, void *), void *pushp,
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bool bip144)
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{
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int res;
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size_t len, written;
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u8 *serialized;;
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u8 flag = 0;
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if (bip144 && uses_witness(tx))
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flag |= WALLY_TX_FLAG_USE_WITNESS;
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res = wally_tx_get_length(tx->wtx, flag, &len);
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assert(res == WALLY_OK);
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serialized = tal_arr(tmpctx, u8, len);
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res = wally_tx_to_bytes(tx->wtx, flag, serialized, len, &written);
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assert(res == WALLY_OK);
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assert(len == written);
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push(serialized, len, pushp);
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tal_free(serialized);
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}
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static void push_sha(const void *data, size_t len, void *shactx_)
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{
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struct sha256_ctx *ctx = shactx_;
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sha256_update(ctx, memcheck(data, len), len);
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}
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static void push_linearize(const void *data, size_t len, void *pptr_)
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{
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u8 **pptr = pptr_;
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size_t oldsize = tal_count(*pptr);
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tal_resize(pptr, oldsize + len);
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memcpy(*pptr + oldsize, memcheck(data, len), len);
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}
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u8 *linearize_tx(const tal_t *ctx, const struct bitcoin_tx *tx)
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{
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u8 *arr = tal_arr(ctx, u8, 0);
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push_tx(tx, NULL, 0, push_linearize, &arr, true);
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return arr;
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}
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size_t bitcoin_tx_weight(const struct bitcoin_tx *tx)
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{
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size_t weight;
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int ret = wally_tx_get_weight(tx->wtx, &weight);
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assert(ret == WALLY_OK);
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return weight;
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}
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void bitcoin_txid(const struct bitcoin_tx *tx, struct bitcoin_txid *txid)
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{
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struct sha256_ctx ctx = SHA256_INIT;
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/* For TXID, we never use extended form. */
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push_tx(tx, NULL, 0, push_sha, &ctx, false);
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sha256_double_done(&ctx, &txid->shad);
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}
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/* Use the bitcoin_tx destructor to also free the wally_tx */
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static void bitcoin_tx_destroy(struct bitcoin_tx *tx)
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{
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wally_tx_free(tx->wtx);
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}
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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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{
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struct bitcoin_tx *tx = tal(ctx, struct bitcoin_tx);
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assert(chainparams);
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/* If we are constructing an elements transaction we need to
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* explicitly add the fee as an extra output. So allocate one more
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* than the outputs we need internally. */
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if (chainparams->is_elements)
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output_count += 1;
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wally_tx_init_alloc(WALLY_TX_VERSION_2, 0, input_count, output_count,
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&tx->wtx);
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tal_add_destructor(tx, bitcoin_tx_destroy);
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tx->input_amounts = tal_arrz(tx, struct amount_sat*, input_count);
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tx->wtx->locktime = 0;
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tx->wtx->version = 2;
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tx->chainparams = chainparams;
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return tx;
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}
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struct bitcoin_tx *pull_bitcoin_tx(const tal_t *ctx, const u8 **cursor,
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size_t *max)
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{
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size_t wsize;
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int flags = WALLY_TX_FLAG_USE_WITNESS;
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struct bitcoin_tx *tx = tal(ctx, struct bitcoin_tx);
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if (chainparams->is_elements)
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flags |= WALLY_TX_FLAG_USE_ELEMENTS;
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if (wally_tx_from_bytes(*cursor, *max, flags, &tx->wtx) != WALLY_OK) {
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fromwire_fail(cursor, max);
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return tal_free(tx);
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}
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tal_add_destructor(tx, bitcoin_tx_destroy);
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/* For whatever reason the length computation gets upset if we tell it
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* that we are using elements. It wants to discover it on its own, NO
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* CLUES! (Ms. Doyle)
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*
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* https://github.com/ElementsProject/libwally-core/issues/139
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*/
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wally_tx_get_length(tx->wtx, flags & ~WALLY_TX_FLAG_USE_ELEMENTS,
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&wsize);
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/* We don't know the input amounts yet, so set them all to NULL */
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tx->input_amounts =
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tal_arrz(tx, struct amount_sat *, tx->wtx->inputs_allocation_len);
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tx->chainparams = chainparams;
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*cursor += wsize;
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*max -= wsize;
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return tx;
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}
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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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{
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const char *end;
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u8 *linear_tx;
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const u8 *p;
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struct bitcoin_tx *tx;
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size_t len;
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end = memchr(hex, '\n', hexlen);
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if (!end)
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end = hex + hexlen;
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len = hex_data_size(end - hex);
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p = linear_tx = tal_arr(ctx, u8, len);
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if (!hex_decode(hex, end - hex, linear_tx, len))
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goto fail;
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tx = pull_bitcoin_tx(ctx, &p, &len);
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if (!tx)
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goto fail;
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if (len)
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goto fail_free_tx;
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tal_free(linear_tx);
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return tx;
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fail_free_tx:
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tal_free(tx);
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fail:
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tal_free(linear_tx);
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return NULL;
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}
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/* <sigh>. Bitcoind represents hashes as little-endian for RPC. */
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static void reverse_bytes(u8 *arr, size_t len)
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{
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unsigned int i;
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for (i = 0; i < len / 2; i++) {
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unsigned char tmp = arr[i];
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arr[i] = arr[len - 1 - i];
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arr[len - 1 - i] = tmp;
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}
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}
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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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{
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if (!hex_decode(hexstr, hexstr_len, txid, sizeof(*txid)))
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return false;
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reverse_bytes(txid->shad.sha.u.u8, sizeof(txid->shad.sha.u.u8));
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return true;
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}
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bool bitcoin_txid_to_hex(const struct bitcoin_txid *txid,
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|
char *hexstr, size_t hexstr_len)
|
|
{
|
|
struct sha256_double rev = txid->shad;
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|
reverse_bytes(rev.sha.u.u8, sizeof(rev.sha.u.u8));
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return hex_encode(&rev, sizeof(rev), hexstr, hexstr_len);
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|
}
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|
|
|
static char *fmt_bitcoin_tx(const tal_t *ctx, const struct bitcoin_tx *tx)
|
|
{
|
|
u8 *lin = linearize_tx(ctx, tx);
|
|
char *s = tal_hex(ctx, lin);
|
|
tal_free(lin);
|
|
return s;
|
|
}
|
|
|
|
static char *fmt_bitcoin_txid(const tal_t *ctx, const struct bitcoin_txid *txid)
|
|
{
|
|
char *hexstr = tal_arr(ctx, char, hex_str_size(sizeof(*txid)));
|
|
|
|
bitcoin_txid_to_hex(txid, hexstr, hex_str_size(sizeof(*txid)));
|
|
return hexstr;
|
|
}
|
|
|
|
REGISTER_TYPE_TO_STRING(bitcoin_tx, fmt_bitcoin_tx);
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|
REGISTER_TYPE_TO_STRING(bitcoin_txid, fmt_bitcoin_txid);
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|
|