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#include "../key_derive.c"
#include <inttypes.h>
#include <stdio.h>
#include <type_to_string.h>
static bool print_superverbose;
#define SUPERVERBOSE(...) \
do { if (print_superverbose) printf(__VA_ARGS__); } while(0)
#define PRINT_ACTUAL_FEE
#include "../commit_tx.c"
#include "../htlc_tx.c"
#include <bitcoin/preimage.h>
#include <bitcoin/privkey.h>
#include <bitcoin/pubkey.h>
#include <ccan/array_size/array_size.h>
#include <ccan/err/err.h>
#include <ccan/str/hex/hex.h>
#include <type_to_string.h>
/* Turn this on to brute-force fee values */
/*#define DEBUG */
static struct sha256 sha256_from_hex(const char *hex)
{
struct sha256 sha256;
if (strstarts(hex, "0x"))
hex += 2;
if (!hex_decode(hex, strlen(hex), &sha256, sizeof(sha256)))
abort();
return sha256;
}
/* bitcoind loves its backwards txids! */
static struct sha256_double txid_from_hex(const char *hex)
{
struct sha256_double sha256;
struct sha256 rev = sha256_from_hex(hex);
size_t i;
for (i = 0; i < sizeof(rev); i++)
sha256.sha.u.u8[sizeof(sha256) - 1 - i] = rev.u.u8[i];
return sha256;
}
static struct privkey privkey_from_hex(const char *hex)
{
struct privkey pk;
size_t len;
if (strstarts(hex, "0x"))
hex += 2;
len = strlen(hex);
/* BOLT #3:
*
* private keys are displayed as 32 bytes plus a trailing 1 (bitcoin's
* convention for "compressed" private keys, i.e. keys for which the
* public key is compressed)
*/
if (len == 66 && strends(hex, "01"))
len -= 2;
if (!hex_decode(hex, len, &pk, sizeof(pk)))
abort();
return pk;
}
static void tx_must_be_eq(const struct bitcoin_tx *a,
const struct bitcoin_tx *b)
{
tal_t *tmpctx = tal_tmpctx(NULL);
u8 *lina, *linb;
size_t i, len;
lina = linearize_tx(tmpctx, a);
linb = linearize_tx(tmpctx, b);
len = tal_len(lina);
if (tal_len(linb) < len)
len = tal_len(linb);
for (i = 0; i < tal_len(lina); i++) {
if (i >= tal_len(linb))
errx(1, "Second tx is truncated:\n"
"%s\n"
"%s",
tal_hex(tmpctx, lina),
tal_hex(tmpctx, linb));
if (lina[i] != linb[i])
errx(1, "tx differ at offset %zu:\n"
"%s\n"
"%s",
i,
tal_hex(tmpctx, lina),
tal_hex(tmpctx, linb));
}
if (i != tal_len(linb))
errx(1, "First tx is truncated:\n"
"%s\n"
"%s",
tal_hex(tmpctx, lina),
tal_hex(tmpctx, linb));
tal_free(tmpctx);
}
/* BOLT #3:
*
* htlc 0 direction: remote->local
* htlc 0 amount_msat: 1000000
* htlc 0 expiry: 500
* htlc 0 payment_preimage: 0000000000000000000000000000000000000000000000000000000000000000
* htlc 1 direction: remote->local
* htlc 1 amount_msat: 2000000
* htlc 1 expiry: 501
* htlc 1 payment_preimage: 0101010101010101010101010101010101010101010101010101010101010101
* htlc 2 direction: local->remote
* htlc 2 amount_msat: 2000000
* htlc 2 expiry: 502
* htlc 2 payment_preimage: 0202020202020202020202020202020202020202020202020202020202020202
* htlc 3 direction: local->remote
* htlc 3 amount_msat: 3000000
* htlc 3 expiry: 503
* htlc 3 payment_preimage: 0303030303030303030303030303030303030303030303030303030303030303
* htlc 4 direction: remote->local
* htlc 4 amount_msat: 4000000
* htlc 4 expiry: 504
* htlc 4 payment_preimage: 0404040404040404040404040404040404040404040404040404040404040404
*/
static const struct htlc **setup_htlcs(const tal_t *ctx)
{
const struct htlc **htlcs = tal_arr(ctx, const struct htlc *, 5);
int i;
for (i = 0; i < 5; i++) {
struct htlc *htlc = tal(htlcs, struct htlc);
htlc->id = i;
switch (i) {
case 0:
htlc->state = RCVD_ADD_ACK_REVOCATION;
htlc->msatoshi = 1000000;
break;
case 1:
htlc->state = RCVD_ADD_ACK_REVOCATION;
htlc->msatoshi = 2000000;
break;
case 2:
htlc->state = SENT_ADD_ACK_REVOCATION;
htlc->msatoshi = 2000000;
break;
case 3:
htlc->state = SENT_ADD_ACK_REVOCATION;
htlc->msatoshi = 3000000;
break;
case 4:
htlc->state = RCVD_ADD_ACK_REVOCATION;
htlc->msatoshi = 4000000;
break;
}
if (i == 0 || i == 1 || i == 4) {
/* direction: remote->local */
} else {
/* direction: local->remote */
htlc->state = SENT_ADD_ACK_REVOCATION;
}
htlc->expiry.locktime = 500 + i;
htlc->r = tal(htlc, struct preimage);
memset(htlc->r, i, sizeof(*htlc->r));
sha256(&htlc->rhash, htlc->r, sizeof(*htlc->r));
htlcs[i] = htlc;
}
return htlcs;
}
#if 0
static struct pubkey pubkey_from_hex(const char *hex)
{
struct pubkey pubkey;
if (strstarts(hex, "0x"))
hex += 2;
if (!pubkey_from_hexstr(hex, strlen(hex), &pubkey))
abort();
return pubkey;
}
#endif
static void report_htlcs(const struct bitcoin_tx *tx,
const struct htlc **htlc_map,
u16 to_self_delay,
const struct privkey *local_secretkey,
const struct pubkey *localkey,
const struct pubkey *local_delayedkey,
const struct privkey *x_remote_secretkey,
const struct pubkey *remotekey,
const struct pubkey *local_revocation_key,
u64 feerate_per_kw)
{
tal_t *tmpctx = tal_tmpctx(NULL);
size_t i, n;
struct sha256_double txid;
struct bitcoin_tx **htlc_tx;
secp256k1_ecdsa_signature *remotesig;
u8 **wscript;
htlc_tx = tal_arrz(tmpctx, struct bitcoin_tx *, tal_count(htlc_map));
remotesig = tal_arr(tmpctx, secp256k1_ecdsa_signature,
tal_count(htlc_map));
wscript = tal_arr(tmpctx, u8 *, tal_count(htlc_map));
bitcoin_txid(tx, &txid);
/* First report remote signatures, in order we would receive them. */
n = 0;
for (i = 0; i < tal_count(htlc_map); i++)
n += (htlc_map[i] != NULL);
printf("num_htlcs: %zu\n", n);
for (i = 0; i < tal_count(htlc_map); i++) {
const struct htlc *htlc = htlc_map[i];
if (!htlc)
continue;
if (htlc_owner(htlc) == LOCAL) {
htlc_tx[i] = htlc_timeout_tx(htlc_tx, &txid, i,
htlc, to_self_delay,
local_revocation_key,
local_delayedkey,
feerate_per_kw);
wscript[i] = bitcoin_wscript_htlc_offer(tmpctx,
localkey,
remotekey,
&htlc->rhash,
local_revocation_key);
} else {
htlc_tx[i] = htlc_success_tx(htlc_tx, &txid, i,
htlc, to_self_delay,
local_revocation_key,
local_delayedkey,
feerate_per_kw);
wscript[i] = bitcoin_wscript_htlc_receive(tmpctx,
&htlc->expiry,
localkey,
remotekey,
&htlc->rhash,
local_revocation_key);
}
sign_tx_input(htlc_tx[i], 0,
NULL,
wscript[i],
x_remote_secretkey, remotekey,
&remotesig[i]);
printf("# signature for output %zi (htlc %zu)\n", i, htlc->id);
printf("remote_htlc_signature = %s\n",
type_to_string(tmpctx, secp256k1_ecdsa_signature,
&remotesig[i]));
}
/* For any HTLC outputs, produce htlc_tx */
for (i = 0; i < tal_count(htlc_map); i++) {
secp256k1_ecdsa_signature localsig;
const struct htlc *htlc = htlc_map[i];
if (!htlc)
continue;
sign_tx_input(htlc_tx[i], 0,
NULL,
wscript[i],
local_secretkey, localkey,
&localsig);
printf("# local_signature = %s\n",
type_to_string(tmpctx, secp256k1_ecdsa_signature,
&localsig));
if (htlc_owner(htlc) == LOCAL) {
htlc_timeout_tx_add_witness(htlc_tx[i],
localkey, remotekey,
&htlc->rhash,
local_revocation_key,
&localsig, &remotesig[i]);
} else {
htlc_success_tx_add_witness(htlc_tx[i],
&htlc->expiry,
localkey, remotekey,
&localsig, &remotesig[i],
htlc->r,
local_revocation_key);
}
printf("output htlc_%s_tx %"PRIu64": %s\n",
htlc_owner(htlc) == LOCAL ? "timeout" : "success",
htlc->id,
tal_hex(tmpctx, linearize_tx(tmpctx, htlc_tx[i])));
}
tal_free(tmpctx);
}
static void report(struct bitcoin_tx *tx,
const u8 *wscript,
const struct privkey *x_remote_funding_privkey,
const struct pubkey *remote_funding_pubkey,
const struct privkey *local_funding_privkey,
const struct pubkey *local_funding_pubkey,
u16 to_self_delay,
const struct privkey *local_secretkey,
const struct pubkey *localkey,
const struct pubkey *local_delayedkey,
const struct privkey *x_remote_secretkey,
const struct pubkey *remotekey,
const struct pubkey *local_revocation_key,
u64 feerate_per_kw,
const struct htlc **htlc_map)
{
tal_t *tmpctx = tal_tmpctx(NULL);
char *txhex;
secp256k1_ecdsa_signature localsig, remotesig;
sign_tx_input(tx, 0,
NULL,
wscript,
x_remote_funding_privkey, remote_funding_pubkey,
&remotesig);
printf("remote_signature = %s\n",
type_to_string(tmpctx, secp256k1_ecdsa_signature, &remotesig));
sign_tx_input(tx, 0,
NULL,
wscript,
local_funding_privkey, local_funding_pubkey,
&localsig);
printf("# local_signature = %s\n",
type_to_string(tmpctx, secp256k1_ecdsa_signature, &localsig));
tx->input[0].witness = bitcoin_witness_2of2(tx->input,
&localsig, &remotesig,
local_funding_pubkey,
remote_funding_pubkey);
txhex = tal_hex(tmpctx, linearize_tx(tx, tx));
printf("output commit_tx: %s\n", txhex);
report_htlcs(tx, htlc_map, to_self_delay,
local_secretkey, localkey,
local_delayedkey,
x_remote_secretkey,
remotekey,
local_revocation_key,
feerate_per_kw);
tal_free(tmpctx);
}
#ifdef DEBUG
static u64 calc_fee(const struct bitcoin_tx *tx, u64 input_satoshi)
{
size_t i;
u64 output_satoshi = 0;
for (i = 0; i < tal_count(tx->output); i++)
output_satoshi += tx->output[i].amount;
return input_satoshi - output_satoshi;
}
/* For debugging, we do brute-force increase to find thresholds */
static u64 increase(u64 feerate_per_kw)
{
return feerate_per_kw + 1;
}
#else
static u64 increase(u64 feerate_per_kw)
{
/* BOLT #3:
*
* local_feerate_per_kw: 0
* ...
* local_feerate_per_kw: 677
* ...
* local_feerate_per_kw: 2162
* ...
* local_feerate_per_kw: 2292
* ...
* local_feerate_per_kw: 3867
* ...
* local_feerate_per_kw: 5134
* ...
* local_feerate_per_kw: 9651181
*/
const u64 rates[] = { 0, 677, 2162, 2292, 3867, 5134, 9651181 };
size_t i;
for (i = 0; i < ARRAY_SIZE(rates); i++)
if (rates[i] == feerate_per_kw)
return rates[i+1];
abort();
}
#endif
/* HTLCs as seen from other side. */
static const struct htlc **invert_htlcs(const struct htlc **htlcs)
{
size_t i, n = tal_count(htlcs);
const struct htlc **inv = tal_arr(htlcs, const struct htlc *, n);
for (i = 0; i < n; i++) {
struct htlc *htlc;
inv[i] = htlc = tal_dup(inv, struct htlc, htlcs[i]);
if (inv[i]->state == RCVD_ADD_ACK_REVOCATION)
htlc->state = SENT_ADD_ACK_REVOCATION;
else {
assert(inv[i]->state == SENT_ADD_ACK_REVOCATION);
htlc->state = RCVD_ADD_ACK_REVOCATION;
}
}
return inv;
}
int main(void)
{
tal_t *tmpctx = tal_tmpctx(NULL);
struct sha256_double funding_txid;
u64 funding_amount_satoshi, dust_limit_satoshi, feerate_per_kw;
u16 to_self_delay;
/* x_ prefix means internal vars we used to derive spec */
struct privkey local_funding_privkey, x_remote_funding_privkey;
struct privkey x_local_payment_basepoint_secret, x_remote_payment_basepoint_secret;
struct privkey x_local_per_commitment_secret;
struct privkey x_local_delayed_payment_basepoint_secret;
struct privkey x_local_revocation_basepoint_secret;
struct privkey local_secretkey, x_remote_secretkey;
struct privkey x_local_delayed_secretkey;
struct pubkey local_funding_pubkey, remote_funding_pubkey;
struct pubkey local_payment_basepoint, remote_payment_basepoint;
struct pubkey x_local_delayed_payment_basepoint;
struct pubkey x_local_revocation_basepoint;
struct pubkey x_local_per_commitment_point;
struct pubkey localkey, remotekey, tmpkey;
struct pubkey local_delayedkey;
struct pubkey local_revocation_key;
struct bitcoin_tx *tx, *tx2;
u8 *wscript;
unsigned int funding_output_index;
u64 commitment_number, cn_obscurer, to_local_msat, to_remote_msat;
const struct htlc **htlcs = setup_htlcs(tmpctx), **htlc_map, **htlc_map2,
**inv_htlcs = invert_htlcs(htlcs);
secp256k1_ctx = secp256k1_context_create(SECP256K1_CONTEXT_VERIFY
| SECP256K1_CONTEXT_SIGN);
/* BOLT #3:
*
* # Appendix C: Commitment and HTLC Transaction Test Vectors
*
* In the following:
* - we consider *local* transactions, which implies that all payments
* to *local* are delayed
* - we assume that *local* is the funder
* - private keys are displayed as 32 bytes plus a trailing 1
* (bitcoin's convention for "compressed" private keys, i.e. keys
* for which the public key is compressed)
*
* - transaction signatures are all deterministic, using
* RFC6979 (using HMAC-SHA256)
*
* We start by defining common basic parameters for each test vector:
* the HTLCs are not used for the first "simple commitment tx with no
* HTLCs" test.
*
* funding_tx_id: 8984484a580b825b9972d7adb15050b3ab624ccd731946b3eeddb92f4e7ef6be
* funding_output_index: 0
* funding_amount_satoshi: 10000000
* commitment_number: 42
* local_delay: 144
* local_dust_limit_satoshi: 546
*/
funding_txid = txid_from_hex("8984484a580b825b9972d7adb15050b3ab624ccd731946b3eeddb92f4e7ef6be");
funding_output_index = 0;
funding_amount_satoshi = 10000000;
commitment_number = 42;
to_self_delay = 144;
dust_limit_satoshi = 546;
#ifdef DEBUG
print_superverbose = true;
#endif
/* BOLT #3:
*
* <!-- We derive the test vector values as per Key Derivation, though
* it's not required for this test. They're included here for
* completeness and in case someone wants to reproduce the test
* vectors themselves:
*
* INTERNAL: remote_funding_privkey: 1552dfba4f6cf29a62a0af13c8d6981d36d0ef8d61ba10fb0fe90da7634d7e130101
* INTERNAL: local_payment_basepoint_secret: 111111111111111111111111111111111111111111111111111111111111111101
* INTERNAL: local_revocation_basepoint_secret: 222222222222222222222222222222222222222222222222222222222222222201
* INTERNAL: local_delayed_payment_basepoint_secret: 333333333333333333333333333333333333333333333333333333333333333301
* INTERNAL: remote_payment_basepoint_secret: 444444444444444444444444444444444444444444444444444444444444444401
* x_local_per_commitment_secret: 1f1e1d1c1b1a191817161514131211100f0e0d0c0b0a0908070605040302010001
* # From local_revocation_basepoint_secret
* INTERNAL: local_revocation_basepoint: 02466d7fcae563e5cb09a0d1870bb580344804617879a14949cf22285f1bae3f27
* # From local_delayed_payment_basepoint_secret
* INTERNAL: local_delayed_payment_basepoint: 023c72addb4fdf09af94f0c94d7fe92a386a7e70cf8a1d85916386bb2535c7b1b1
* INTERNAL: local_per_commitment_point: 025f7117a78150fe2ef97db7cfc83bd57b2e2c0d0dd25eaf467a4a1c2a45ce1486
* INTERNAL: remote_secretkey: 839ad0480cde69fc721fb8e919dcf20bc4f2b3374c7b27ff37f200ddfa7b0edb01
* # From local_delayed_payment_basepoint_secret, local_per_commitment_point and local_delayed_payment_basepoint
* INTERNAL: local_delayed_secretkey: adf3464ce9c2f230fd2582fda4c6965e4993ca5524e8c9580e3df0cf226981ad01
*/
local_funding_privkey = privkey_from_hex("30ff4956bbdd3222d44cc5e8a1261dab1e07957bdac5ae88fe3261ef321f374901");
x_remote_funding_privkey = privkey_from_hex("1552dfba4f6cf29a62a0af13c8d6981d36d0ef8d61ba10fb0fe90da7634d7e1301");
SUPERVERBOSE("INTERNAL: remote_funding_privkey: %s01\n",
type_to_string(tmpctx, struct privkey,
&x_remote_funding_privkey));
x_local_payment_basepoint_secret = privkey_from_hex("1111111111111111111111111111111111111111111111111111111111111111");
SUPERVERBOSE("INTERNAL: local_payment_basepoint_secret: %s\n",
type_to_string(tmpctx, struct privkey,
&x_local_payment_basepoint_secret));
x_local_revocation_basepoint_secret = privkey_from_hex("2222222222222222222222222222222222222222222222222222222222222222");
SUPERVERBOSE("INTERNAL: local_revocation_basepoint_secret: %s\n",
type_to_string(tmpctx, struct privkey,
&x_local_revocation_basepoint_secret));
x_local_delayed_payment_basepoint_secret = privkey_from_hex("3333333333333333333333333333333333333333333333333333333333333333");
SUPERVERBOSE("INTERNAL: local_delayed_payment_basepoint_secret: %s\n",
type_to_string(tmpctx, struct privkey,
&x_local_delayed_payment_basepoint_secret));
x_remote_payment_basepoint_secret = privkey_from_hex("4444444444444444444444444444444444444444444444444444444444444444");
SUPERVERBOSE("INTERNAL: remote_payment_basepoint_secret: %s\n",
type_to_string(tmpctx, struct privkey,
&x_remote_payment_basepoint_secret));
x_local_per_commitment_secret = privkey_from_hex("0x1f1e1d1c1b1a191817161514131211100f0e0d0c0b0a09080706050403020100");
SUPERVERBOSE("x_local_per_commitment_secret: %s\n",
type_to_string(tmpctx, struct privkey,
&x_local_per_commitment_secret));
if (!pubkey_from_privkey(&x_local_revocation_basepoint_secret,
&x_local_revocation_basepoint))
abort();
SUPERVERBOSE("# From local_revocation_basepoint_secret\n"
"INTERNAL: local_revocation_basepoint: %s\n",
type_to_string(tmpctx, struct pubkey,
&x_local_revocation_basepoint));
if (!pubkey_from_privkey(&x_local_delayed_payment_basepoint_secret,
&x_local_delayed_payment_basepoint))
abort();
SUPERVERBOSE("# From local_delayed_payment_basepoint_secret\n"
"INTERNAL: local_delayed_payment_basepoint: %s\n",
type_to_string(tmpctx, struct pubkey,
&x_local_delayed_payment_basepoint));
if (!pubkey_from_privkey(&x_local_per_commitment_secret,
&x_local_per_commitment_point))
abort();
SUPERVERBOSE("INTERNAL: local_per_commitment_point: %s\n",
type_to_string(tmpctx, struct pubkey,
&x_local_per_commitment_point));
if (!pubkey_from_privkey(&x_local_payment_basepoint_secret,
&local_payment_basepoint))
abort();
if (!pubkey_from_privkey(&x_remote_payment_basepoint_secret,
&remote_payment_basepoint))
abort();
if (!derive_simple_privkey(&x_remote_payment_basepoint_secret,
&remote_payment_basepoint,
&x_local_per_commitment_point,
&x_remote_secretkey))
abort();
SUPERVERBOSE("INTERNAL: remote_secretkey: %s\n",
type_to_string(tmpctx, struct privkey, &x_remote_secretkey));
if (!derive_simple_privkey(&x_local_delayed_payment_basepoint_secret,
&x_local_delayed_payment_basepoint,
&x_local_per_commitment_point,
&x_local_delayed_secretkey))
abort();
SUPERVERBOSE("# From local_delayed_payment_basepoint_secret, local_per_commitment_point and local_delayed_payment_basepoint\n"
"INTERNAL: local_delayed_secretkey: %s\n",
type_to_string(tmpctx, struct privkey,
&x_local_delayed_secretkey));
/* These two needed to calculate obscuring factor */
printf("local_payment_basepoint: %s\n",
type_to_string(tmpctx, struct pubkey, &local_payment_basepoint));
printf("remote_payment_basepoint: %s\n",
type_to_string(tmpctx, struct pubkey,&remote_payment_basepoint));
cn_obscurer = commit_number_obscurer(&local_payment_basepoint,
&remote_payment_basepoint);
printf("# obscured commitment transaction number = 0x%"PRIx64" ^ %"PRIu64"\n",
cn_obscurer, commitment_number);
printf("local_funding_privkey: %s01\n",
type_to_string(tmpctx, struct privkey, &local_funding_privkey));
if (!pubkey_from_privkey(&local_funding_privkey, &local_funding_pubkey))
abort();
printf("local_funding_pubkey: %s\n",
type_to_string(tmpctx, struct pubkey, &local_funding_pubkey));
if (!pubkey_from_privkey(&x_remote_funding_privkey, &remote_funding_pubkey))
abort();
printf("remote_funding_pubkey: %s\n",
type_to_string(tmpctx, struct pubkey, &remote_funding_pubkey));
if (!derive_simple_privkey(&x_local_payment_basepoint_secret,
&local_payment_basepoint,
&x_local_per_commitment_point,
&local_secretkey))
abort();
printf("local_secretkey: %s\n",
type_to_string(tmpctx, struct privkey, &local_secretkey));
if (!pubkey_from_privkey(&local_secretkey, &localkey))
abort();
if (!derive_simple_key(&local_payment_basepoint,
&x_local_per_commitment_point,
&tmpkey))
abort();
assert(pubkey_eq(&tmpkey, &localkey));
printf("localkey: %s\n",
type_to_string(tmpctx, struct pubkey, &localkey));
if (!derive_simple_key(&remote_payment_basepoint,
&x_local_per_commitment_point,
&remotekey))
abort();
printf("remotekey: %s\n",
type_to_string(tmpctx, struct pubkey, &remotekey));
if (!pubkey_from_privkey(&x_local_delayed_secretkey, &local_delayedkey))
abort();
if (!derive_simple_key(&x_local_delayed_payment_basepoint,
&x_local_per_commitment_point,
&tmpkey))
abort();
assert(pubkey_eq(&tmpkey, &local_delayedkey));
printf("local_delayedkey: %s\n",
type_to_string(tmpctx, struct pubkey, &local_delayedkey));
if (!derive_revocation_key(&x_local_revocation_basepoint,
&x_local_per_commitment_point,
&local_revocation_key))
abort();
printf("local_revocation_key: %s\n",
type_to_string(tmpctx, struct pubkey, &local_revocation_key));
wscript = bitcoin_redeem_2of2(tmpctx, &local_funding_pubkey,
&remote_funding_pubkey);
printf("# funding wscript = %s\n", tal_hex(tmpctx, wscript));
/* BOLT #3:
*
* name: simple commitment tx with no HTLCs
* to_local_msat: 7000000000
* to_remote_msat: 3000000000
* feerate_per_kw: 15000
*/
to_local_msat = 7000000000;
to_remote_msat = 3000000000;
feerate_per_kw = 15000;
printf("\n"
"name: simple commitment tx with no HTLCs\n"
"to_local_msat: %"PRIu64"\n"
"to_remote_msat: %"PRIu64"\n"
"feerate_per_kw: %"PRIu64"\n",
to_local_msat, to_remote_msat, feerate_per_kw);
print_superverbose = true;
tx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
NULL, &htlc_map, commitment_number ^ cn_obscurer,
LOCAL);
print_superverbose = false;
tx2 = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
REMOTE, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
NULL, &htlc_map2, commitment_number ^ cn_obscurer,
REMOTE);
tx_must_be_eq(tx, tx2);
report(tx, wscript, &x_remote_funding_privkey, &remote_funding_pubkey,
&local_funding_privkey, &local_funding_pubkey,
to_self_delay,
&local_secretkey,
&localkey,
&local_delayedkey,
&x_remote_secretkey,
&remotekey,
&local_revocation_key,
feerate_per_kw,
htlc_map);
/* BOLT #3:
*
* name: commitment tx with all 5 htlcs untrimmed (minimum feerate)
* to_local_msat: 6988000000
* to_remote_msat: 3000000000
* local_feerate_per_kw: 0
*/
to_local_msat = 6988000000;
to_remote_msat = 3000000000;
feerate_per_kw = 0;
printf("\n"
"name: commitment tx with all 5 htlcs untrimmed (minimum feerate)\n"
"to_local_msat: %"PRIu64"\n"
"to_remote_msat: %"PRIu64"\n"
"local_feerate_per_kw: %"PRIu64"\n",
to_local_msat, to_remote_msat, feerate_per_kw);
print_superverbose = true;
tx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
htlcs, &htlc_map, commitment_number ^ cn_obscurer,
LOCAL);
print_superverbose = false;
tx2 = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
REMOTE, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
inv_htlcs, &htlc_map2,
commitment_number ^ cn_obscurer,
REMOTE);
tx_must_be_eq(tx, tx2);
report(tx, wscript, &x_remote_funding_privkey, &remote_funding_pubkey,
&local_funding_privkey, &local_funding_pubkey,
to_self_delay,
&local_secretkey,
&localkey,
&local_delayedkey,
&x_remote_secretkey,
&remotekey,
&local_revocation_key,
feerate_per_kw,
htlc_map);
do {
struct bitcoin_tx *newtx;
feerate_per_kw = increase(feerate_per_kw);
print_superverbose = false;
newtx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
htlcs, &htlc_map,
commitment_number ^ cn_obscurer,
LOCAL);
/* This is what it would look like for peer generating it! */
tx2 = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
REMOTE, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
inv_htlcs, &htlc_map2,
commitment_number ^ cn_obscurer,
REMOTE);
tx_must_be_eq(newtx, tx2);
#ifdef DEBUG
if (feerate_per_kw % 100000 == 0)
printf("feerate_per_kw = %"PRIu64", fees = %"PRIu64"\n",
feerate_per_kw, calc_fee(newtx, funding_amount_satoshi));
if (tal_count(newtx->output) == tal_count(tx->output)) {
tal_free(newtx);
continue;
}
#endif
printf("\n"
"name: commitment tx with %zu output%s untrimmed (maximum feerate)\n"
"to_local_msat: %"PRIu64"\n"
"to_remote_msat: %"PRIu64"\n"
"local_feerate_per_kw: %"PRIu64"\n",
tal_count(tx->output),
tal_count(tx->output) > 1 ? "s" : "",
to_local_msat, to_remote_msat, feerate_per_kw-1);
/* Recalc with verbosity on */
print_superverbose = true;
tx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw-1,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
htlcs, &htlc_map,
commitment_number ^ cn_obscurer,
LOCAL);
report(tx, wscript,
&x_remote_funding_privkey, &remote_funding_pubkey,
&local_funding_privkey, &local_funding_pubkey,
to_self_delay,
&local_secretkey,
&localkey,
&local_delayedkey,
&x_remote_secretkey,
&remotekey,
&local_revocation_key,
feerate_per_kw-1,
htlc_map);
printf("\n"
"name: commitment tx with %zu output%s untrimmed (minimum feerate)\n"
"to_local_msat: %"PRIu64"\n"
"to_remote_msat: %"PRIu64"\n"
"local_feerate_per_kw: %"PRIu64"\n",
tal_count(newtx->output),
tal_count(newtx->output) > 1 ? "s" : "",
to_local_msat, to_remote_msat, feerate_per_kw);
/* Recalc with verbosity on */
print_superverbose = true;
newtx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
htlcs, &htlc_map,
commitment_number ^ cn_obscurer,
LOCAL);
report(newtx, wscript,
&x_remote_funding_privkey, &remote_funding_pubkey,
&local_funding_privkey, &local_funding_pubkey,
to_self_delay,
&local_secretkey,
&localkey,
&local_delayedkey,
&x_remote_secretkey,
&remotekey,
&local_revocation_key,
feerate_per_kw,
htlc_map);
assert(tal_count(newtx->output) != tal_count(tx->output));
tal_free(tx);
tx = newtx;
} while (tal_count(tx->output) > 1);
/* Now make sure we cover case where funder can't afford the fee;
* its output cannot go negative! */
for (;;) {
u64 base_fee_msat = commit_tx_base_fee(feerate_per_kw, 0)
* 1000;
if (base_fee_msat <= to_local_msat) {
feerate_per_kw++;
continue;
}
/* BOLT #3:
*
* name: commitment tx with fee greater than funder amount
* to_local_msat: 6988000000
* to_remote_msat: 3000000000
* local_feerate_per_kw: 9651936
*/
assert(feerate_per_kw == 9651936);
printf("\n"
"name: commitment tx with fee greater than funder amount\n"
"to_local_msat: %"PRIu64"\n"
"to_remote_msat: %"PRIu64"\n"
"local_feerate_per_kw: %"PRIu64"\n",
to_local_msat, to_remote_msat, feerate_per_kw);
tx = commit_tx(tmpctx, &funding_txid, funding_output_index,
funding_amount_satoshi,
LOCAL, to_self_delay,
&local_revocation_key,
&local_delayedkey,
&localkey,
&remotekey,
feerate_per_kw,
dust_limit_satoshi,
to_local_msat,
to_remote_msat,
htlcs, &htlc_map,
commitment_number ^ cn_obscurer,
LOCAL);
report(tx, wscript,
&x_remote_funding_privkey, &remote_funding_pubkey,
&local_funding_privkey, &local_funding_pubkey,
to_self_delay,
&local_secretkey,
&localkey,
&local_delayedkey,
&x_remote_secretkey,
&remotekey,
&local_revocation_key,
feerate_per_kw,
htlc_map);
break;
}
/* No memory leaks please */
secp256k1_context_destroy(secp256k1_ctx);
tal_free(tmpctx);
/* FIXME: Do BOLT comparison! */
return 0;
}