#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Nobody will ever find it here! */ static struct { struct secret hsm_secret; struct ext_key bip32; } secretstuff; struct client { struct daemon_conn dc; struct daemon_conn *master; struct pubkey id; struct io_plan *(*handle)(struct io_conn *, struct daemon_conn *); /* What is this client allowed to ask for? */ u64 capabilities; }; /* Function declarations for later */ static void init_hsm(struct daemon_conn *master, const u8 *msg); static void pass_client_hsmfd(struct daemon_conn *master, const u8 *msg); static void sign_funding_tx(struct daemon_conn *master, const u8 *msg); static void sign_invoice(struct daemon_conn *master, const u8 *msg); static void sign_node_announcement(struct daemon_conn *master, const u8 *msg); static void sign_withdrawal_tx(struct daemon_conn *master, const u8 *msg); static void node_key(struct privkey *node_privkey, struct pubkey *node_id) { u32 salt = 0; struct privkey unused_s; struct pubkey unused_k; if (node_privkey == NULL) node_privkey = &unused_s; else if (node_id == NULL) node_id = &unused_k; do { hkdf_sha256(node_privkey, sizeof(*node_privkey), &salt, sizeof(salt), &secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret), "nodeid", 6); salt++; } while (!secp256k1_ec_pubkey_create(secp256k1_ctx, &node_id->pubkey, node_privkey->secret.data)); } static struct client *new_client(struct daemon_conn *master, const struct pubkey *id, const u64 capabilities, struct io_plan *(*handle)(struct io_conn *, struct daemon_conn *), int fd) { struct client *c = tal(master, struct client); if (id) { c->id = *id; } else { memset(&c->id, 0, sizeof(c->id)); } c->handle = handle; c->master = master; c->capabilities = capabilities; daemon_conn_init(c, &c->dc, fd, handle, NULL); /* Free the connection if we exit everything. */ tal_steal(master, c->dc.conn); /* Free client when connection freed. */ tal_steal(c->dc.conn, c); return c; } static struct io_plan *handle_ecdh(struct io_conn *conn, struct daemon_conn *dc) { struct client *c = container_of(dc, struct client, dc); struct privkey privkey; struct pubkey point; struct secret ss; if (!fromwire_hsm_ecdh_req(dc->msg_in, NULL, &point)) { daemon_conn_send(c->master, take(towire_hsmstatus_client_bad_request(c, &c->id, dc->msg_in))); return io_close(conn); } node_key(&privkey, NULL); if (secp256k1_ecdh(secp256k1_ctx, ss.data, &point.pubkey, privkey.secret.data) != 1) { status_broken("secp256k1_ecdh fail for client %s", type_to_string(trc, struct pubkey, &c->id)); daemon_conn_send(c->master, take(towire_hsmstatus_client_bad_request(c, &c->id, dc->msg_in))); return io_close(conn); } daemon_conn_send(dc, take(towire_hsm_ecdh_resp(c, &ss))); return daemon_conn_read_next(conn, dc); } static struct io_plan *handle_cannouncement_sig(struct io_conn *conn, struct daemon_conn *dc) { tal_t *ctx = tal_tmpctx(conn); /* First 2 + 256 byte are the signatures and msg type, skip them */ size_t offset = 258; struct privkey node_pkey; secp256k1_ecdsa_signature node_sig; struct sha256_double hash; u8 *reply; u8 *ca; struct pubkey bitcoin_id; if (!fromwire_hsm_cannouncement_sig_req(ctx, dc->msg_in, NULL, &bitcoin_id, &ca)) { status_broken("Failed to parse cannouncement_sig_req: %s", tal_hex(trc, dc->msg_in)); return io_close(conn); } if (tal_len(ca) < offset) { status_broken("bad cannounce length %zu", tal_len(ca)); return io_close(conn); } /* TODO(cdecker) Check that this is actually a valid * channel_announcement */ node_key(&node_pkey, NULL); sha256_double(&hash, ca + offset, tal_len(ca) - offset); sign_hash(&node_pkey, &hash, &node_sig); reply = towire_hsm_cannouncement_sig_reply(ca, &node_sig); daemon_conn_send(dc, take(reply)); tal_free(ctx); return daemon_conn_read_next(conn, dc); } static struct io_plan *handle_channel_update_sig(struct io_conn *conn, struct daemon_conn *dc) { tal_t *tmpctx = tal_tmpctx(conn); /* 2 bytes msg type + 64 bytes signature */ size_t offset = 66; struct privkey node_pkey; struct sha256_double hash; secp256k1_ecdsa_signature sig; struct short_channel_id scid; u32 timestamp, fee_base_msat, fee_proportional_mill; u64 htlc_minimum_msat; u16 flags, cltv_expiry_delta; struct bitcoin_blkid chain_hash; u8 *cu; if (!fromwire_hsm_cupdate_sig_req(tmpctx, dc->msg_in, NULL, &cu)) { status_broken("Failed to parse %s: %s", hsm_client_wire_type_name(fromwire_peektype(dc->msg_in)), tal_hex(trc, dc->msg_in)); return io_close(conn); } if (!fromwire_channel_update(cu, NULL, &sig, &chain_hash, &scid, ×tamp, &flags, &cltv_expiry_delta, &htlc_minimum_msat, &fee_base_msat, &fee_proportional_mill)) { status_broken("Failed to parse inner channel_update: %s", tal_hex(trc, dc->msg_in)); return io_close(conn); } if (tal_len(cu) < offset) { status_broken("inner channel_update too short: %s", tal_hex(trc, dc->msg_in)); return io_close(conn); } node_key(&node_pkey, NULL); sha256_double(&hash, cu + offset, tal_len(cu) - offset); sign_hash(&node_pkey, &hash, &sig); cu = towire_channel_update(tmpctx, &sig, &chain_hash, &scid, timestamp, flags, cltv_expiry_delta, htlc_minimum_msat, fee_base_msat, fee_proportional_mill); daemon_conn_send(dc, take(towire_hsm_cupdate_sig_reply(tmpctx, cu))); tal_free(tmpctx); return daemon_conn_read_next(conn, dc); } static bool check_client_capabilities(struct client *client, enum hsm_client_wire_type t) { switch (t) { case WIRE_HSM_ECDH_REQ: return (client->capabilities & HSM_CAP_ECDH) != 0; case WIRE_HSM_CANNOUNCEMENT_SIG_REQ: case WIRE_HSM_CUPDATE_SIG_REQ: case WIRE_HSM_NODE_ANNOUNCEMENT_SIG_REQ: return (client->capabilities & HSM_CAP_SIGN_GOSSIP) != 0; case WIRE_HSM_INIT: case WIRE_HSM_CLIENT_HSMFD: case WIRE_HSM_SIGN_FUNDING: case WIRE_HSM_SIGN_WITHDRAWAL: case WIRE_HSM_SIGN_INVOICE: return (client->capabilities & HSM_CAP_MASTER) != 0; /* These are messages sent by the HSM so we should never receive * them */ case WIRE_HSM_ECDH_RESP: case WIRE_HSM_CANNOUNCEMENT_SIG_REPLY: case WIRE_HSM_CUPDATE_SIG_REPLY: case WIRE_HSM_CLIENT_HSMFD_REPLY: case WIRE_HSM_SIGN_FUNDING_REPLY: case WIRE_HSM_NODE_ANNOUNCEMENT_SIG_REPLY: case WIRE_HSM_SIGN_WITHDRAWAL_REPLY: case WIRE_HSM_SIGN_INVOICE_REPLY: case WIRE_HSM_INIT_REPLY: case WIRE_HSMSTATUS_CLIENT_BAD_REQUEST: break; } return false; } static struct io_plan *handle_client(struct io_conn *conn, struct daemon_conn *dc) { struct client *c = container_of(dc, struct client, dc); enum hsm_client_wire_type t = fromwire_peektype(dc->msg_in); status_debug("Client: Received message %d from client", t); /* Before we do anything else, is this client allowed to do * what he asks for? */ if (!check_client_capabilities(c, t)) { status_broken("Client does not have the required capability to run %d", t); daemon_conn_send(c->master, take(towire_hsmstatus_client_bad_request( c, &c->id, dc->msg_in))); return io_close(conn); } /* Now actually go and do what the client asked for */ switch (t) { case WIRE_HSM_INIT: init_hsm(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_CLIENT_HSMFD: pass_client_hsmfd(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_ECDH_REQ: return handle_ecdh(conn, dc); case WIRE_HSM_CANNOUNCEMENT_SIG_REQ: return handle_cannouncement_sig(conn, dc); case WIRE_HSM_CUPDATE_SIG_REQ: return handle_channel_update_sig(conn, dc); case WIRE_HSM_SIGN_FUNDING: sign_funding_tx(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_NODE_ANNOUNCEMENT_SIG_REQ: sign_node_announcement(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_SIGN_INVOICE: sign_invoice(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_SIGN_WITHDRAWAL: sign_withdrawal_tx(dc, dc->msg_in); return daemon_conn_read_next(conn, dc); case WIRE_HSM_ECDH_RESP: case WIRE_HSM_CANNOUNCEMENT_SIG_REPLY: case WIRE_HSM_CUPDATE_SIG_REPLY: case WIRE_HSM_CLIENT_HSMFD_REPLY: case WIRE_HSM_SIGN_FUNDING_REPLY: case WIRE_HSM_NODE_ANNOUNCEMENT_SIG_REPLY: case WIRE_HSM_SIGN_WITHDRAWAL_REPLY: case WIRE_HSM_SIGN_INVOICE_REPLY: case WIRE_HSM_INIT_REPLY: case WIRE_HSMSTATUS_CLIENT_BAD_REQUEST: break; } daemon_conn_send(c->master, take(towire_hsmstatus_client_bad_request(c, &c->id, dc->msg_in))); return io_close(conn); } /** * hsm_peer_secret_base -- Derive the base secret seed for per-peer seeds * * This secret is shared by all channels/peers for the client. The * per-peer seeds will be generated from it by mixing in the * channel_id and the peer node_id. */ static void hsm_peer_secret_base(struct secret *peer_seed_base) { hkdf_sha256(peer_seed_base, sizeof(struct secret), NULL, 0, &secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret), "peer seed", strlen("peer seed")); } static void send_init_response(struct daemon_conn *master) { struct pubkey node_id; struct secret peer_seed; u8 *msg; hsm_peer_secret_base(&peer_seed); node_key(NULL, &node_id); msg = towire_hsm_init_reply(master, &node_id, &peer_seed, &secretstuff.bip32); daemon_conn_send(master, take(msg)); } static void populate_secretstuff(void) { u8 bip32_seed[BIP32_ENTROPY_LEN_256]; u32 salt = 0; struct ext_key master_extkey, child_extkey; /* Fill in the BIP32 tree for bitcoin addresses. */ do { hkdf_sha256(bip32_seed, sizeof(bip32_seed), &salt, sizeof(salt), &secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret), "bip32 seed", strlen("bip32 seed")); salt++; } while (bip32_key_from_seed(bip32_seed, sizeof(bip32_seed), BIP32_VER_TEST_PRIVATE, 0, &master_extkey) != WALLY_OK); /* BIP 32: * * The default wallet layout * * An HDW is organized as several 'accounts'. Accounts are numbered, * the default account ("") being number 0. Clients are not required * to support more than one account - if not, they only use the * default account. * * Each account is composed of two keypair chains: an internal and an * external one. The external keychain is used to generate new public * addresses, while the internal keychain is used for all other * operations (change addresses, generation addresses, ..., anything * that doesn't need to be communicated). Clients that do not support * separate keychains for these should use the external one for * everything. * * - m/iH/0/k corresponds to the k'th keypair of the external chain of account number i of the HDW derived from master m. */ /* Hence child 0, then child 0 again to get extkey to derive from. */ if (bip32_key_from_parent(&master_extkey, 0, BIP32_FLAG_KEY_PRIVATE, &child_extkey) != WALLY_OK) status_failed(STATUS_FAIL_INTERNAL_ERROR, "Can't derive child bip32 key"); if (bip32_key_from_parent(&child_extkey, 0, BIP32_FLAG_KEY_PRIVATE, &secretstuff.bip32) != WALLY_OK) status_failed(STATUS_FAIL_INTERNAL_ERROR, "Can't derive private bip32 key"); } static void bitcoin_pubkey(struct pubkey *pubkey, u32 index) { struct ext_key ext; if (index >= BIP32_INITIAL_HARDENED_CHILD) status_failed(STATUS_FAIL_MASTER_IO, "Index %u too great", index); if (bip32_key_from_parent(&secretstuff.bip32, index, BIP32_FLAG_KEY_PUBLIC, &ext) != WALLY_OK) status_failed(STATUS_FAIL_INTERNAL_ERROR, "BIP32 of %u failed", index); if (!secp256k1_ec_pubkey_parse(secp256k1_ctx, &pubkey->pubkey, ext.pub_key, sizeof(ext.pub_key))) status_failed(STATUS_FAIL_INTERNAL_ERROR, "Parse of BIP32 child %u pubkey failed", index); } static void bitcoin_keypair(struct privkey *privkey, struct pubkey *pubkey, u32 index) { struct ext_key ext; if (index >= BIP32_INITIAL_HARDENED_CHILD) status_failed(STATUS_FAIL_MASTER_IO, "Index %u too great", index); if (bip32_key_from_parent(&secretstuff.bip32, index, BIP32_FLAG_KEY_PRIVATE, &ext) != WALLY_OK) status_failed(STATUS_FAIL_INTERNAL_ERROR, "BIP32 of %u failed", index); /* libwally says: The private key with prefix byte 0 */ memcpy(privkey->secret.data, ext.priv_key+1, 32); if (!secp256k1_ec_pubkey_create(secp256k1_ctx, &pubkey->pubkey, privkey->secret.data)) status_failed(STATUS_FAIL_INTERNAL_ERROR, "BIP32 pubkey %u create failed", index); } static void create_new_hsm(struct daemon_conn *master) { int fd = open("hsm_secret", O_CREAT|O_EXCL|O_WRONLY, 0400); if (fd < 0) status_failed(STATUS_FAIL_INTERNAL_ERROR, "creating: %s", strerror(errno)); randombytes_buf(&secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret)); if (!write_all(fd, &secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret))) { unlink_noerr("hsm_secret"); status_failed(STATUS_FAIL_INTERNAL_ERROR, "writing: %s", strerror(errno)); } if (fsync(fd) != 0) { unlink_noerr("hsm_secret"); status_failed(STATUS_FAIL_INTERNAL_ERROR, "fsync: %s", strerror(errno)); } if (close(fd) != 0) { unlink_noerr("hsm_secret"); status_failed(STATUS_FAIL_INTERNAL_ERROR, "closing: %s", strerror(errno)); } fd = open(".", O_RDONLY); if (fd < 0) { status_failed(STATUS_FAIL_INTERNAL_ERROR, "opening: %s", strerror(errno)); } if (fsync(fd) != 0) { unlink_noerr("hsm_secret"); status_failed(STATUS_FAIL_INTERNAL_ERROR, "fsyncdir: %s", strerror(errno)); } close(fd); populate_secretstuff(); } static void load_hsm(struct daemon_conn *master) { int fd = open("hsm_secret", O_RDONLY); if (fd < 0) status_failed(STATUS_FAIL_INTERNAL_ERROR, "opening: %s", strerror(errno)); if (!read_all(fd, &secretstuff.hsm_secret, sizeof(secretstuff.hsm_secret))) status_failed(STATUS_FAIL_INTERNAL_ERROR, "reading: %s", strerror(errno)); close(fd); populate_secretstuff(); } static void init_hsm(struct daemon_conn *master, const u8 *msg) { bool new; if (!fromwire_hsm_init(msg, NULL, &new)) master_badmsg(WIRE_HSM_INIT, msg); if (new) create_new_hsm(master); else load_hsm(master); send_init_response(master); } static void pass_client_hsmfd(struct daemon_conn *master, const u8 *msg) { int fds[2]; u64 capabilities; struct pubkey id; if (!fromwire_hsm_client_hsmfd(msg, NULL, &id, &capabilities)) master_badmsg(WIRE_HSM_CLIENT_HSMFD, msg); if (socketpair(AF_UNIX, SOCK_STREAM, 0, fds) != 0) status_failed(STATUS_FAIL_INTERNAL_ERROR, "creating fds: %s", strerror(errno)); new_client(master, &id, capabilities, handle_client, fds[0]); daemon_conn_send(master, take(towire_hsm_client_hsmfd_reply(master))); daemon_conn_send_fd(master, fds[1]); } static void derive_peer_seed(struct privkey *peer_seed, struct privkey *peer_seed_base, const struct pubkey *peer_id, const u64 channel_id) { u8 input[PUBKEY_DER_LEN + sizeof(channel_id)]; char *info = "per-peer seed"; pubkey_to_der(input, peer_id); memcpy(input + PUBKEY_DER_LEN, &channel_id, sizeof(channel_id)); hkdf_sha256(peer_seed, sizeof(*peer_seed), input, sizeof(input), peer_seed_base, sizeof(*peer_seed_base), info, strlen(info)); } static void hsm_unilateral_close_privkey(struct privkey *dst, struct unilateral_close_info *info) { struct privkey peer_seed, peer_seed_base; struct basepoints basepoints; struct secrets secrets; hsm_peer_secret_base(&peer_seed_base.secret); derive_peer_seed(&peer_seed, &peer_seed_base, &info->peer_id, info->channel_id); derive_basepoints(&peer_seed, NULL, &basepoints, &secrets, NULL); if (!derive_simple_privkey(&secrets.payment_basepoint_secret, &basepoints.payment, &info->commitment_point, dst)) { status_failed(STATUS_FAIL_INTERNAL_ERROR, "Deriving unilateral_close_privkey"); } } /** * hsm_key_for_utxo - generate the keypair matching the utxo */ static void hsm_key_for_utxo(struct privkey *privkey, struct pubkey *pubkey, const struct utxo *utxo) { if (utxo->close_info != NULL) { /* This is a their_unilateral_close/to-us output, so * we need to derive the secret the long way */ status_debug("Unilateral close output, deriving secrets"); hsm_unilateral_close_privkey(privkey, utxo->close_info); pubkey_from_privkey(privkey, pubkey); status_debug("Derived public key %s from unilateral close", type_to_string(trc, struct pubkey, pubkey)); } else { /* Simple case: just get derive via HD-derivation */ bitcoin_keypair(privkey, pubkey, utxo->keyindex); } } /* Note that it's the main daemon that asks for the funding signature so it * can broadcast it. */ static void sign_funding_tx(struct daemon_conn *master, const u8 *msg) { const tal_t *tmpctx = tal_tmpctx(master); u64 satoshi_out, change_out; u32 change_keyindex; struct pubkey local_pubkey, remote_pubkey; struct utxo *inputs; const struct utxo **utxomap; struct bitcoin_tx *tx; u8 *wscript; u16 outnum; size_t i; struct pubkey changekey; u8 **scriptSigs; /* FIXME: Check fee is "reasonable" */ if (!fromwire_hsm_sign_funding(tmpctx, msg, NULL, &satoshi_out, &change_out, &change_keyindex, &local_pubkey, &remote_pubkey, &inputs)) master_badmsg(WIRE_HSM_SIGN_FUNDING, msg); utxomap = to_utxoptr_arr(tmpctx, inputs); if (change_out) bitcoin_pubkey(&changekey, change_keyindex); tx = funding_tx(tmpctx, &outnum, utxomap, satoshi_out, &local_pubkey, &remote_pubkey, change_out, &changekey, NULL); scriptSigs = tal_arr(tmpctx, u8*, tal_count(inputs)); for (i = 0; i < tal_count(inputs); i++) { struct pubkey inkey; struct privkey inprivkey; const struct utxo *in = utxomap[i]; u8 *subscript; secp256k1_ecdsa_signature sig; hsm_key_for_utxo(&inprivkey, &inkey, in); if (in->is_p2sh) subscript = bitcoin_redeem_p2sh_p2wpkh(tmpctx, &inkey); else subscript = NULL; wscript = p2wpkh_scriptcode(tmpctx, &inkey); sign_tx_input(tx, i, subscript, wscript, &inprivkey, &inkey, &sig); tx->input[i].witness = bitcoin_witness_p2wpkh(tx, &sig, &inkey); if (inputs[i].is_p2sh) scriptSigs[i] = bitcoin_scriptsig_p2sh_p2wpkh(tx, &inkey); else scriptSigs[i] = NULL; } /* Now complete the transaction by attaching the scriptSigs where necessary */ for (size_t i=0; iinput[i].script = scriptSigs[i]; daemon_conn_send(master, take(towire_hsm_sign_funding_reply(tmpctx, tx))); tal_free(tmpctx); } /** * sign_withdrawal_tx - Generate and sign a withdrawal transaction from the master */ static void sign_withdrawal_tx(struct daemon_conn *master, const u8 *msg) { const tal_t *tmpctx = tal_tmpctx(master); u64 satoshi_out, change_out; u32 change_keyindex; struct utxo *inutxos; const struct utxo **utxos; u8 *wscript; u8 **scriptSigs; struct bitcoin_tx *tx; struct ext_key ext; struct pubkey changekey; u8 *scriptpubkey; if (!fromwire_hsm_sign_withdrawal(tmpctx, msg, NULL, &satoshi_out, &change_out, &change_keyindex, &scriptpubkey, &inutxos)) { status_broken("Failed to parse sign_withdrawal: %s", tal_hex(trc, msg)); return; } if (bip32_key_from_parent(&secretstuff.bip32, change_keyindex, BIP32_FLAG_KEY_PUBLIC, &ext) != WALLY_OK) { status_broken("Failed to parse sign_withdrawal: %s", tal_hex(trc, msg)); return; } /* We need an array of pointers, since withdraw_tx permutes them */ utxos = to_utxoptr_arr(tmpctx, inutxos); pubkey_from_der(ext.pub_key, sizeof(ext.pub_key), &changekey); tx = withdraw_tx( tmpctx, utxos, scriptpubkey, satoshi_out, &changekey, change_out, NULL); scriptSigs = tal_arr(tmpctx, u8*, tal_count(utxos)); for (size_t i = 0; i < tal_count(utxos); i++) { struct pubkey inkey; struct privkey inprivkey; const struct utxo *in = utxos[i]; u8 *subscript; secp256k1_ecdsa_signature sig; hsm_key_for_utxo(&inprivkey, &inkey, in); if (in->is_p2sh || in->close_info != NULL) subscript = bitcoin_redeem_p2sh_p2wpkh(tmpctx, &inkey); else subscript = NULL; wscript = p2wpkh_scriptcode(tmpctx, &inkey); sign_tx_input(tx, i, subscript, wscript, &inprivkey, &inkey, &sig); tx->input[i].witness = bitcoin_witness_p2wpkh(tx, &sig, &inkey); if (utxos[i]->is_p2sh) scriptSigs[i] = bitcoin_scriptsig_p2sh_p2wpkh(tx, &inkey); else scriptSigs[i] = NULL; } /* Now complete the transaction by attaching the scriptSigs where necessary */ for (size_t i=0; iinput[i].script = scriptSigs[i]; daemon_conn_send(master, take(towire_hsm_sign_withdrawal_reply(tmpctx, tx))); tal_free(tmpctx); } /** * sign_invoice - Sign an invoice with our key. */ static void sign_invoice(struct daemon_conn *master, const u8 *msg) { const tal_t *tmpctx = tal_tmpctx(master); u5 *u5bytes; u8 *hrpu8; char *hrp; struct sha256 sha; secp256k1_ecdsa_recoverable_signature rsig; struct hash_u5 hu5; struct privkey node_pkey; if (!fromwire_hsm_sign_invoice(tmpctx, msg, NULL, &u5bytes, &hrpu8)) { status_broken("Failed to parse sign_invoice: %s", tal_hex(trc, msg)); return; } /* FIXME: Check invoice! */ hrp = tal_dup_arr(tmpctx, char, (char *)hrpu8, tal_len(hrpu8), 1); hrp[tal_len(hrpu8)] = '\0'; hash_u5_init(&hu5, hrp); hash_u5(&hu5, u5bytes, tal_len(u5bytes)); hash_u5_done(&hu5, &sha); node_key(&node_pkey, NULL); if (!secp256k1_ecdsa_sign_recoverable(secp256k1_ctx, &rsig, (const u8 *)&sha, node_pkey.secret.data, NULL, NULL)) { status_failed(STATUS_FAIL_INTERNAL_ERROR, "Failed to sign invoice: %s", tal_hex(trc, msg)); } daemon_conn_send(master, take(towire_hsm_sign_invoice_reply(tmpctx, &rsig))); tal_free(tmpctx); } static void sign_node_announcement(struct daemon_conn *master, const u8 *msg) { /* 2 bytes msg type + 64 bytes signature */ size_t offset = 66; struct sha256_double hash; struct privkey node_pkey; secp256k1_ecdsa_signature sig; u8 *reply; u8 *ann; if (!fromwire_hsm_node_announcement_sig_req(msg, msg, NULL, &ann)) { status_failed(STATUS_FAIL_GOSSIP_IO, "Failed to parse node_announcement_sig_req: %s", tal_hex(trc, msg)); } if (tal_len(ann) < offset) { status_failed(STATUS_FAIL_GOSSIP_IO, "Node announcement too short: %s", tal_hex(trc, msg)); } /* FIXME(cdecker) Check the node announcement's content */ node_key(&node_pkey, NULL); sha256_double(&hash, ann + offset, tal_len(ann) - offset); sign_hash(&node_pkey, &hash, &sig); reply = towire_hsm_node_announcement_sig_reply(msg, &sig); daemon_conn_send(master, take(reply)); } #ifndef TESTING /* FIXME: This is used by debug.c, but doesn't apply to us. */ extern void dev_disconnect_init(int fd); void dev_disconnect_init(int fd) { } static void master_gone(struct io_conn *unused, struct daemon_conn *dc) { /* Can't tell master, it's gone. */ exit(2); } int main(int argc, char *argv[]) { struct client *client; subdaemon_setup(argc, argv); io_poll_override(debug_poll); client = new_client(NULL, NULL, HSM_CAP_MASTER | HSM_CAP_SIGN_GOSSIP, handle_client, STDIN_FILENO); /* We're our own master! */ client->master = &client->dc; io_set_finish(client->dc.conn, master_gone, &client->dc); status_setup_async(&client->dc); /* When conn closes, everything is freed. */ tal_steal(client->dc.conn, client); io_loop(NULL, NULL); return 0; } #endif