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554 lines
14 KiB
554 lines
14 KiB
#include "tx.h"
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#include <assert.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 <stdio.h>
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enum styles {
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/* Add the CT padding stuff to amount. */
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TX_AMOUNT_CT_STYLE = 1,
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/* Whether to process CT rangeproof and noncecommitment. */
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TX_AMOUNT_INCLUDE_CT = 2,
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/* Process the txfee field. */
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TX_FEE = 4,
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/* Process the input script sig. */
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TX_INPUT_SCRIPTSIG = 8,
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/* Process the amounts for each input. */
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TX_INPUT_AMOUNT = 16,
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/* Process the same amounts for each input. */
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TX_INPUT_AMOUNT_BUGGY = 32,
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/* Process hash of rangeproof and noncecommitment in *output* amount,
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* instead of rangeproof and noncecommitment themselves. */
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TX_OUTPUT_AMOUNT_HASHPROOF = 64
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};
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#ifdef ALPHA_TXSTYLE
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/* Linearizing has everything, except input amount (which is implied) */
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#define LINEARIZE_STYLE (TX_AMOUNT_CT_STYLE | TX_AMOUNT_INCLUDE_CT | TX_FEE | TX_INPUT_SCRIPTSIG)
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/* Alpha txids don't include input scripts, or rangeproof/txcommit in output */
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#define TXID_STYLE (TX_AMOUNT_CT_STYLE | TX_FEE)
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/* Alpha signatures sign the input script (assuming others are set to
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* 0-len), as well as the input fee.
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* They sign a hash of the rangeproof and noncecommitment for inputs,
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* rather than the non rangeproof and noncecommitment themselves.
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*
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* For some reason they skip the txfee. */
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#define SIG_STYLE (TX_AMOUNT_CT_STYLE | TX_AMOUNT_INCLUDE_CT | TX_INPUT_SCRIPTSIG | TX_INPUT_AMOUNT | TX_INPUT_AMOUNT_BUGGY | TX_OUTPUT_AMOUNT_HASHPROOF)
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#else /* BITCOIN */
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/* Process all the bitcoin fields. Works for txid, serialization and signing */
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#define LINEARIZE_STYLE (TX_INPUT_SCRIPTSIG)
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#define TXID_STYLE (TX_INPUT_SCRIPTSIG)
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#define SIG_STYLE (TX_INPUT_SCRIPTSIG)
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#endif
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static void add_varint(varint_t v,
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void (*add)(const void *, size_t, void *), void *addp,
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enum styles style)
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{
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u8 buf[9], *p = buf;
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if (v < 0xfd) {
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*(p++) = v;
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} else if (v <= 0xffff) {
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(*p++) = 0xfd;
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(*p++) = v;
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(*p++) = v >> 8;
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} else if (v <= 0xffffffff) {
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(*p++) = 0xfe;
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(*p++) = v;
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(*p++) = v >> 8;
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(*p++) = v >> 16;
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(*p++) = v >> 24;
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} else {
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(*p++) = 0xff;
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(*p++) = v;
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(*p++) = v >> 8;
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(*p++) = v >> 16;
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(*p++) = v >> 24;
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(*p++) = v >> 32;
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(*p++) = v >> 40;
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(*p++) = v >> 48;
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(*p++) = v >> 56;
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}
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add(buf, p - buf, addp);
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}
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static void add_le32(u32 v,
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void (*add)(const void *, size_t, void *), void *addp,
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enum styles style)
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{
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le32 l = cpu_to_le32(v);
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add(&l, sizeof(l), addp);
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}
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static void add_le64(u64 v,
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void (*add)(const void *, size_t, void *), void *addp,
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enum styles style)
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{
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le64 l = cpu_to_le64(v);
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add(&l, sizeof(l), addp);
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}
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static void add_value(u64 amount,
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void (*add)(const void *, size_t, void *),
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void *addp,
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bool output,
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enum styles style)
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{
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if (style & TX_AMOUNT_CT_STYLE) {
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/* The input is hashed as a 33 byte value (for CT); 25 0, then
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* the big-endian value. */
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static u8 zeroes[25];
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be64 b = cpu_to_be64(amount);
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add(zeroes, sizeof(zeroes), addp);
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add(&b, sizeof(b), addp);
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if (style & TX_AMOUNT_INCLUDE_CT) {
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/* Two more zeroes: Rangeproof and Noncecommitment */
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if (output && (style & TX_OUTPUT_AMOUNT_HASHPROOF)) {
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struct sha256_double h;
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sha256_double(&h, zeroes, 2);
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add(&h, sizeof(h), addp);
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} else {
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add_varint(0, add, addp, style);
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add_varint(0, add, addp, style);
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}
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}
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} else {
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add_le64(amount, add, addp, style);
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}
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}
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static void add_input_value(u64 amount,
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void (*add)(const void *, size_t, void *),
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void *addp,
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enum styles style)
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{
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return add_value(amount, add, addp, false, style);
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}
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static void add_output_value(u64 amount,
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void (*add)(const void *, size_t, void *),
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void *addp,
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enum styles style)
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{
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return add_value(amount, add, addp, true, style);
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}
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static void add_tx_input(const struct bitcoin_tx_input *input,
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void (*add)(const void *, size_t, void *), void *addp,
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u64 dummy_amount,
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enum styles style)
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{
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add(&input->txid, sizeof(input->txid), addp);
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add_le32(input->index, add, addp, style);
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if (style & TX_INPUT_AMOUNT) {
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if (style & TX_INPUT_AMOUNT_BUGGY)
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add_input_value(dummy_amount, add, addp, style);
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else
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add_input_value(input->input_amount, add, addp, style);
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}
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if (style & TX_INPUT_SCRIPTSIG) {
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add_varint(input->script_length, add, addp, style);
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add(input->script, input->script_length, addp);
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}
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add_le32(input->sequence_number, add, addp, style);
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}
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static void add_tx_output(const struct bitcoin_tx_output *output,
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void (*add)(const void *, size_t, void *), void *addp,
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enum styles style)
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{
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add_output_value(output->amount, add, addp, style);
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add_varint(output->script_length, add, addp, style);
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add(output->script, output->script_length, addp);
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}
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static void add_tx(const struct bitcoin_tx *tx,
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void (*add)(const void *, size_t, void *), void *addp,
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u64 dummy_amount,
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enum styles style)
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{
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varint_t i;
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add_le32(tx->version, add, addp, style);
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add_varint(tx->input_count, add, addp, style);
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for (i = 0; i < tx->input_count; i++)
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add_tx_input(&tx->input[i], add, addp, dummy_amount, style);
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if (style & TX_FEE)
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add_le64(tx->fee, add, addp, style);
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add_varint(tx->output_count, add, addp, style);
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for (i = 0; i < tx->output_count; i++)
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add_tx_output(&tx->output[i], add, addp, style);
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add_le32(tx->lock_time, add, addp, style);
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}
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static void add_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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void sha256_tx_for_sig(struct sha256_ctx *ctx, const struct bitcoin_tx *tx,
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unsigned int input_num)
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{
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size_t i;
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/* Caller should zero-out other scripts for signing! */
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assert(input_num < tx->input_count);
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for (i = 0; i < tx->input_count; i++)
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if (i != input_num)
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assert(tx->input[i].script_length == 0);
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add_tx(tx, add_sha, ctx, tx->input[input_num].input_amount, SIG_STYLE);
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}
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static void add_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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add_tx(tx, add_linearize, &arr, 0, LINEARIZE_STYLE);
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return arr;
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}
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void bitcoin_txid(const struct bitcoin_tx *tx, struct sha256_double *txid)
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{
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struct sha256_ctx ctx = SHA256_INIT;
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add_tx(tx, add_sha, &ctx, 0, TXID_STYLE);
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sha256_double_done(&ctx, txid);
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}
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struct bitcoin_tx *bitcoin_tx(const tal_t *ctx, varint_t input_count,
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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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size_t i;
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tx->output_count = output_count;
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tx->output = tal_arrz(tx, struct bitcoin_tx_output, output_count);
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tx->input_count = input_count;
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tx->input = tal_arrz(tx, struct bitcoin_tx_input, input_count);
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for (i = 0; i < tx->input_count; i++) {
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/* We assume NULL is a zero bitmap */
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assert(tx->input[i].script == NULL);
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tx->input[i].sequence_number = 0xFFFFFFFF;
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}
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tx->lock_time = 0;
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#ifdef HAS_BIP68
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tx->version = 2;
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#else
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tx->version = 1;
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#endif
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return tx;
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}
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/* Sets *cursor to NULL and returns NULL when a pull fails. */
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static const u8 *pull(const u8 **cursor, size_t *max, void *copy, size_t n)
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{
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const u8 *p = *cursor;
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if (*max < n) {
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*cursor = NULL;
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*max = 0;
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/* Just make sure we don't leak uninitialized mem! */
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if (copy)
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memset(copy, 0, n);
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return NULL;
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}
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*cursor += n;
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*max -= n;
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if (copy)
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memcpy(copy, p, n);
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return memcheck(p, n);
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}
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static u64 pull_varint(const u8 **cursor, size_t *max)
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{
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u64 ret;
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const u8 *p;
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p = pull(cursor, max, NULL, 1);
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if (!p)
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return 0;
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if (*p < 0xfd) {
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ret = *p;
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} else if (*p == 0xfd) {
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p = pull(cursor, max, NULL, 2);
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if (!p)
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return 0;
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ret = ((u64)p[1] << 8) + p[0];
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} else if (*p == 0xfe) {
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p = pull(cursor, max, NULL, 4);
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if (!p)
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return 0;
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ret = ((u64)p[3] << 24) + ((u64)p[2] << 16)
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+ ((u64)p[1] << 8) + p[0];
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} else {
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p = pull(cursor, max, NULL, 8);
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if (!p)
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return 0;
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ret = ((u64)p[7] << 56) + ((u64)p[6] << 48)
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+ ((u64)p[5] << 40) + ((u64)p[4] << 32)
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+ ((u64)p[3] << 24) + ((u64)p[2] << 16)
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+ ((u64)p[1] << 8) + p[0];
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}
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return ret;
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}
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static u32 pull_le32(const u8 **cursor, size_t *max)
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{
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le32 ret;
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if (!pull(cursor, max, &ret, sizeof(ret)))
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return 0;
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return le32_to_cpu(ret);
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}
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static u64 pull_le64(const u8 **cursor, size_t *max)
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{
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le64 ret;
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if (!pull(cursor, max, &ret, sizeof(ret)))
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return 0;
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return le64_to_cpu(ret);
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}
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static bool pull_sha256_double(const u8 **cursor, size_t *max,
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struct sha256_double *h)
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{
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return pull(cursor, max, h, sizeof(*h));
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}
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static u64 pull_value(const u8 **cursor, size_t *max)
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{
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u64 amount;
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if (LINEARIZE_STYLE & TX_AMOUNT_CT_STYLE) {
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/* The input is hashed as a 33 byte value (for CT); 25 0, then
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* the big-endian value. */
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u8 zeroes[25];
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be64 b;
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if (!pull(cursor, max, zeroes, sizeof(zeroes)))
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return 0;
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/* We don't handle CT amounts. */
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if (zeroes[0] != 0)
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goto fail;
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if (!pull(cursor, max, &b, sizeof(b)))
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return 0;
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amount = be64_to_cpu(b);
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if (LINEARIZE_STYLE & TX_AMOUNT_INCLUDE_CT) {
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varint_t rp, nc;
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rp = pull_varint(cursor, max);
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nc = pull_varint(cursor, max);
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if (rp != 0 || nc != 0)
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goto fail;
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}
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} else {
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amount = pull_le64(cursor, max);
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}
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return amount;
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fail:
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/* Simulate EOF */
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*cursor = NULL;
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*max = 0;
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return 0;
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}
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static void pull_input(const tal_t *ctx, const u8 **cursor, size_t *max,
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struct bitcoin_tx_input *input)
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{
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pull_sha256_double(cursor, max, &input->txid);
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input->index = pull_le32(cursor, max);
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if (LINEARIZE_STYLE & TX_INPUT_AMOUNT) {
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input->input_amount = pull_value(cursor, max);
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}
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if (LINEARIZE_STYLE & TX_INPUT_SCRIPTSIG) {
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input->script_length = pull_varint(cursor, max);
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input->script = tal_arr(ctx, u8, input->script_length);
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pull(cursor, max, input->script, input->script_length);
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}
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input->sequence_number = pull_le32(cursor, max);
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}
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static void pull_output(const tal_t *ctx, const u8 **cursor, size_t *max,
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struct bitcoin_tx_output *output)
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{
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output->amount = pull_value(cursor, max);
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output->script_length = pull_varint(cursor, max);
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output->script = tal_arr(ctx, u8, output->script_length);
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pull(cursor, max, output->script, output->script_length);
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}
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static struct bitcoin_tx *pull_bitcoin_tx(const tal_t *ctx,
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const u8 **cursor, size_t *max)
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{
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struct bitcoin_tx *tx = tal(ctx, struct bitcoin_tx);
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size_t i;
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tx->version = pull_le32(cursor, max);
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tx->input_count = pull_varint(cursor, max);
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tx->input = tal_arr(tx, struct bitcoin_tx_input, tx->input_count);
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for (i = 0; i < tx->input_count; i++)
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pull_input(tx, cursor, max, tx->input + i);
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if (LINEARIZE_STYLE & TX_FEE)
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tx->fee = pull_le64(cursor, max);
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tx->output_count = pull_varint(cursor, max);
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tx->output = tal_arr(tx, struct bitcoin_tx_output, tx->output_count);
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for (i = 0; i < tx->output_count; i++)
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pull_output(tx, cursor, max, tx->output + i);
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tx->lock_time = pull_le32(cursor, max);
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/* If we ran short, or have bytes left over, fail. */
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if (!*cursor || *max != 0)
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tx = tal_free(tx);
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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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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, ':', hexlen);
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if (!end) {
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end = cast_const(char *, hex) + hexlen;
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if (hexlen > 0 && hex[hexlen-1] == '\n')
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end--;
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}
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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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/* Optional appended [:input-amount]* */
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for (len = 0; len < tx->input_count; len++) {
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if (*end != ':')
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break;
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tx->input[len].input_amount = 0;
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end++;
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while (end < hex + hexlen && cisdigit(*end)) {
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tx->input[len].input_amount *= 10;
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tx->input[len].input_amount += *end - '0';
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end++;
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}
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}
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if (len == tx->input_count) {
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if (end != hex + hexlen && *end != '\n')
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goto fail_free_tx;
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} else {
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/* Input amounts are compulsory for alpha, to generate sigs */
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#ifdef ALPHA_TXSTYLE
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goto fail_free_tx;
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#endif
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}
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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. This didn't
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* stick for blockids (everyone else uses big-endian, eg. block explorers),
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* but it did stick for txids. */
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|
static void reverse_bytes(u8 *arr, size_t len)
|
|
{
|
|
unsigned int i;
|
|
|
|
for (i = 0; i < len / 2; i++) {
|
|
unsigned char tmp = arr[i];
|
|
arr[i] = arr[len - 1 - i];
|
|
arr[len - 1 - i] = tmp;
|
|
}
|
|
}
|
|
|
|
bool bitcoin_txid_from_hex(const char *hexstr, size_t hexstr_len,
|
|
struct sha256_double *txid)
|
|
{
|
|
if (!hex_decode(hexstr, hexstr_len, txid, sizeof(*txid)))
|
|
return false;
|
|
reverse_bytes(txid->sha.u.u8, sizeof(txid->sha.u.u8));
|
|
return true;
|
|
}
|
|
|
|
bool bitcoin_txid_to_hex(const struct sha256_double *txid,
|
|
char *hexstr, size_t hexstr_len)
|
|
{
|
|
struct sha256_double rev = *txid;
|
|
reverse_bytes(rev.sha.u.u8, sizeof(rev.sha.u.u8));
|
|
return hex_encode(&rev, sizeof(rev), hexstr, hexstr_len);
|
|
}
|
|
|
|
static bool write_input_amounts(int fd, const struct bitcoin_tx *tx)
|
|
{
|
|
/* Alpha required input amounts, so append them */
|
|
#ifdef ALPHA_TXSTYLE
|
|
size_t i;
|
|
|
|
for (i = 0; i < tx->input_count; i++) {
|
|
char str[1 + STR_MAX_CHARS(tx->input[i].input_amount)];
|
|
sprintf(str, ":%llu",
|
|
(unsigned long long)tx->input[i].input_amount);
|
|
if (!write_all(fd, str, strlen(str)))
|
|
return false;
|
|
}
|
|
#endif
|
|
return true;
|
|
}
|
|
|
|
bool bitcoin_tx_write(int fd, const struct bitcoin_tx *tx)
|
|
{
|
|
u8 *tx_arr;
|
|
char *tx_hex;
|
|
bool ok;
|
|
|
|
tx_arr = linearize_tx(NULL, tx);
|
|
tx_hex = tal_arr(tx_arr, char, hex_str_size(tal_count(tx_arr)));
|
|
hex_encode(tx_arr, tal_count(tx_arr), tx_hex, tal_count(tx_hex));
|
|
|
|
ok = write_all(fd, tx_hex, strlen(tx_hex))
|
|
&& write_input_amounts(fd, tx);
|
|
tal_free(tx_arr);
|
|
return ok;
|
|
}
|
|
|