core-lightning/connectd/connectd.c
Rusty Russell e012e94ab2 hsmd: rename hsm_client_wire_csv to hsm_wire.csv
That matches the other CSV names (HSM was the first, so it was written
before the pattern emerged).

Signed-off-by: Rusty Russell <rusty@rustcorp.com.au>
2018-09-20 09:49:39 +02:00

1347 lines
36 KiB
C

#include <ccan/asort/asort.h>
#include <ccan/build_assert/build_assert.h>
#include <ccan/cast/cast.h>
#include <ccan/container_of/container_of.h>
#include <ccan/crypto/hkdf_sha256/hkdf_sha256.h>
#include <ccan/crypto/siphash24/siphash24.h>
#include <ccan/endian/endian.h>
#include <ccan/fdpass/fdpass.h>
#include <ccan/io/fdpass/fdpass.h>
#include <ccan/io/io.h>
#include <ccan/list/list.h>
#include <ccan/mem/mem.h>
#include <ccan/noerr/noerr.h>
#include <ccan/take/take.h>
#include <ccan/tal/str/str.h>
#include <ccan/timer/timer.h>
#include <common/bech32.h>
#include <common/bech32_util.h>
#include <common/cryptomsg.h>
#include <common/daemon_conn.h>
#include <common/decode_short_channel_ids.h>
#include <common/features.h>
#include <common/ping.h>
#include <common/pseudorand.h>
#include <common/status.h>
#include <common/subdaemon.h>
#include <common/timeout.h>
#include <common/type_to_string.h>
#include <common/utils.h>
#include <common/version.h>
#include <common/wire_error.h>
#include <common/wireaddr.h>
#include <connectd/connectd.h>
#include <connectd/gen_connect_gossip_wire.h>
#include <connectd/gen_connect_wire.h>
#include <connectd/handshake.h>
#include <connectd/netaddress.h>
#include <connectd/tor.h>
#include <connectd/tor_autoservice.h>
#include <errno.h>
#include <gossipd/gen_gossip_wire.h>
#include <hsmd/gen_hsm_wire.h>
#include <inttypes.h>
#include <lightningd/gossip_msg.h>
#include <netdb.h>
#include <netinet/in.h>
#include <secp256k1_ecdh.h>
#include <sodium/randombytes.h>
#include <stdarg.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/un.h>
#include <unistd.h>
#include <wire/gen_peer_wire.h>
#include <wire/peer_wire.h>
#include <wire/wire_io.h>
#include <wire/wire_sync.h>
#include <zlib.h>
#define CONNECT_MAX_REACH_ATTEMPTS 10
#define HSM_FD 3
#define GOSSIPCTL_FD 4
#define INITIAL_WAIT_SECONDS 1
#define MAX_WAIT_SECONDS 300
struct listen_fd {
int fd;
/* If we bind() IPv6 then IPv4 to same port, we *may* fail to listen()
* on the IPv4 socket: under Linux, by default, the IPv6 listen()
* covers IPv4 too. Normally we'd consider failing to listen on a
* port to be fatal, so we note this when setting up addresses. */
bool mayfail;
};
static const struct pubkey *
pubkey_keyof(const struct pubkey *pk)
{
return pk;
}
static size_t pubkey_hash(const struct pubkey *id)
{
return siphash24(siphash_seed(), id, sizeof(*id));
}
HTABLE_DEFINE_TYPE(struct pubkey,
pubkey_keyof,
pubkey_hash,
pubkey_eq,
pubkey_set);
struct daemon {
/* Who am I? */
struct pubkey id;
/* Peers we know of */
struct pubkey_set peers;
/* Peers reconnecting now (waiting for current peer to die). */
struct list_head reconnecting;
/* Peers we are trying to reach */
struct list_head reaching;
/* Connection to main daemon. */
struct daemon_conn master;
struct timers timers;
/* Local and global features to offer to peers. */
u8 *localfeatures, *globalfeatures;
/* Allow localhost to be considered "public" */
bool dev_allow_localhost;
struct addrinfo *proxyaddr;
bool use_proxy_always;
/* @see lightningd.config.use_dns */
bool use_dns;
/* The address that the broken response returns instead of
* NXDOMAIN. NULL if we have not detected a broken resolver. */
struct sockaddr *broken_resolver_response;
/* File descriptors to listen on once we're activated. */
struct listen_fd *listen_fds;
};
/* Peers we're trying to reach. */
struct reaching {
/* daemon->reaching */
struct list_node list;
struct daemon *daemon;
/* The ID of the peer (not necessarily unique, in transit!) */
struct pubkey id;
/* We iterate through the tal_count(addrs) */
size_t addrnum;
struct wireaddr_internal *addrs;
/* NULL if there wasn't a hint. */
struct wireaddr_internal *addrhint;
/* How far did we get? */
const char *connstate;
/* Accumulated errors */
char *errors;
/* How many seconds did we wait this time? */
u32 seconds_waited;
};
/* This is a transitory structure: we hand off to the master daemon as soon
* as we've completed INIT read/write. */
struct peer {
/* For reconnecting peers, this is in daemon->reconnecting. */
struct list_node list;
struct daemon *daemon;
/* The ID of the peer */
struct pubkey id;
/* Where it's connected to. */
struct wireaddr_internal addr;
/* Feature bitmaps. */
u8 *gfeatures, *lfeatures;
/* Cryptostate */
struct peer_crypto_state pcs;
/* Our connection (and owner) */
struct io_conn *conn;
};
/* Mutual recursion */
static void try_reach_one_addr(struct reaching *reach);
static struct peer *find_reconnecting_peer(struct daemon *daemon,
const struct pubkey *id)
{
struct peer *peer;
list_for_each(&daemon->reconnecting, peer, list)
if (pubkey_eq(&peer->id, id))
return peer;
return NULL;
}
static void destroy_reconnecting_peer(struct peer *peer)
{
list_del_from(&peer->daemon->reconnecting, &peer->list);
/* This is safe even if we're being destroyed because of peer->conn,
* since tal_free protects against loops. */
io_close(peer->conn);
}
static void add_reconnecting_peer(struct daemon *daemon, struct peer *peer)
{
/* Drop any previous connecting peer */
tal_free(find_reconnecting_peer(peer->daemon, &peer->id));
list_add_tail(&daemon->reconnecting, &peer->list);
tal_add_destructor(peer, destroy_reconnecting_peer);
}
/**
* Some ISP resolvers will reply with a dummy IP to queries that would otherwise
* result in an NXDOMAIN reply. This just checks whether we have one such
* resolver upstream and remembers its reply so we can try to filter future
* dummies out.
*/
static bool broken_resolver(struct daemon *daemon)
{
struct addrinfo *addrinfo;
struct addrinfo hints;
char *hostname = "nxdomain-test.doesntexist";
int err;
memset(&hints, 0, sizeof(hints));
hints.ai_family = AF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
hints.ai_protocol = 0;
hints.ai_flags = AI_ADDRCONFIG;
err = getaddrinfo(hostname, tal_fmt(tmpctx, "%d", 42),
&hints, &addrinfo);
daemon->broken_resolver_response =
tal_free(daemon->broken_resolver_response);
if (err == 0) {
daemon->broken_resolver_response = tal_dup(daemon, struct sockaddr, addrinfo->ai_addr);
freeaddrinfo(addrinfo);
}
return daemon->broken_resolver_response != NULL;
}
static struct peer *new_peer(struct io_conn *conn,
struct daemon *daemon,
const struct pubkey *their_id,
const struct wireaddr_internal *addr,
const struct crypto_state *cs)
{
struct peer *peer = tal(conn, struct peer);
peer->conn = conn;
peer->id = *their_id;
peer->addr = *addr;
peer->daemon = daemon;
init_peer_crypto_state(peer, &peer->pcs);
peer->pcs.cs = *cs;
return peer;
}
static void destroy_reaching(struct reaching *reach)
{
list_del_from(&reach->daemon->reaching, &reach->list);
}
static struct reaching *find_reaching(struct daemon *daemon,
const struct pubkey *id)
{
struct reaching *r;
list_for_each(&daemon->reaching, r, list)
if (pubkey_eq(id, &r->id))
return r;
return NULL;
}
static void reached_peer(struct peer *peer, struct io_conn *conn)
{
/* OK, we've reached the peer successfully, tell everyone. */
struct reaching *r = find_reaching(peer->daemon, &peer->id);
if (!r)
return;
/* Don't call destroy_io_conn */
io_set_finish(conn, NULL, NULL);
/* Don't free conn with reach */
tal_steal(peer->daemon, conn);
tal_free(r);
}
static int get_gossipfd(struct peer *peer)
{
bool gossip_queries_feature, initial_routing_sync, success;
u8 *msg;
gossip_queries_feature
= feature_offered(peer->lfeatures, LOCAL_GOSSIP_QUERIES)
&& feature_offered(peer->daemon->localfeatures,
LOCAL_GOSSIP_QUERIES);
initial_routing_sync
= feature_offered(peer->lfeatures, LOCAL_INITIAL_ROUTING_SYNC);
/* We do this communication sync. */
msg = towire_gossip_new_peer(NULL, &peer->id, gossip_queries_feature,
initial_routing_sync);
if (!wire_sync_write(GOSSIPCTL_FD, take(msg)))
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed writing to gossipctl: %s",
strerror(errno));
msg = wire_sync_read(peer, GOSSIPCTL_FD);
if (!fromwire_gossip_new_peer_reply(msg, &success))
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed parsing msg gossipctl: %s",
tal_hex(tmpctx, msg));
if (!success) {
status_broken("Gossipd did not give us an fd: losing peer %s",
type_to_string(tmpctx, struct pubkey, &peer->id));
return -1;
}
return fdpass_recv(GOSSIPCTL_FD);
}
static struct io_plan *peer_close_after_error(struct io_conn *conn,
struct peer *peer)
{
status_trace("%s: we sent them a fatal error, closing",
type_to_string(tmpctx, struct pubkey, &peer->id));
return io_close(conn);
}
/* Mutual recursion */
static struct io_plan *peer_connected(struct io_conn *conn, struct peer *peer);
static struct io_plan *retry_peer_connected(struct io_conn *conn,
struct peer *peer)
{
status_trace("peer %s: processing now old peer gone",
type_to_string(tmpctx, struct pubkey, &peer->id));
/* Clean up reconnecting state, try again */
list_del_from(&peer->daemon->reconnecting, &peer->list);
tal_del_destructor(peer, destroy_reconnecting_peer);
return peer_connected(conn, peer);
}
static struct io_plan *peer_connected(struct io_conn *conn, struct peer *peer)
{
struct daemon *daemon = peer->daemon;
u8 *msg;
int gossip_fd;
/* FIXME: We could do this before exchanging init msgs. */
if (pubkey_set_get(&daemon->peers, &peer->id)) {
status_trace("peer %s: reconnect",
type_to_string(tmpctx, struct pubkey, &peer->id));
/* Tell master to kill it: will send peer_disconnect */
msg = towire_connect_reconnected(NULL, &peer->id);
daemon_conn_send(&daemon->master, take(msg));
add_reconnecting_peer(daemon, peer);
return io_wait(conn, peer, retry_peer_connected, peer);
}
reached_peer(peer, conn);
gossip_fd = get_gossipfd(peer);
if (gossip_fd < 0)
return io_close(conn);
msg = towire_connect_peer_connected(tmpctx, &peer->id, &peer->addr,
&peer->pcs.cs,
peer->gfeatures, peer->lfeatures);
daemon_conn_send(&daemon->master, msg);
daemon_conn_send_fd(&daemon->master, io_conn_fd(conn));
daemon_conn_send_fd(&daemon->master, gossip_fd);
pubkey_set_add(&daemon->peers,
tal_dup(daemon, struct pubkey, &peer->id));
/* This frees the peer. */
return io_close_taken_fd(conn);
}
static struct io_plan *peer_init_received(struct io_conn *conn,
struct peer *peer,
u8 *msg)
{
if (!fromwire_init(peer, msg, &peer->gfeatures, &peer->lfeatures)) {
status_trace("peer %s bad fromwire_init '%s', closing",
type_to_string(tmpctx, struct pubkey, &peer->id),
tal_hex(tmpctx, msg));
return io_close(conn);
}
if (!features_supported(peer->gfeatures, peer->lfeatures)) {
const u8 *global_features = get_offered_global_features(msg);
const u8 *local_features = get_offered_local_features(msg);
msg = towire_errorfmt(NULL, NULL, "Unsupported features %s/%s:"
" we only offer globalfeatures %s"
" and localfeatures %s",
tal_hex(msg, peer->gfeatures),
tal_hex(msg, peer->lfeatures),
tal_hexstr(msg,
global_features,
tal_count(global_features)),
tal_hexstr(msg,
local_features,
tal_count(local_features)));
return peer_write_message(conn, &peer->pcs, take(msg),
peer_close_after_error);
}
return peer_connected(conn, peer);
}
static struct io_plan *read_init(struct io_conn *conn, struct peer *peer)
{
/* BOLT #1:
*
* The receiving node:
* - MUST wait to receive `init` before sending any other messages.
*/
return peer_read_message(conn, &peer->pcs, peer_init_received);
}
/* This creates a temporary peer which is not in the list and is owner
* by the connection; it's placed in the list and owned by daemon once
* we have the features. */
static struct io_plan *init_new_peer(struct io_conn *conn,
const struct pubkey *their_id,
const struct wireaddr_internal *addr,
const struct crypto_state *cs,
struct daemon *daemon)
{
struct peer *peer = new_peer(conn, daemon, their_id, addr, cs);
u8 *initmsg;
/* BOLT #1:
*
* The sending node:
* - MUST send `init` as the first Lightning message for any
* connection.
*/
initmsg = towire_init(NULL,
daemon->globalfeatures, daemon->localfeatures);
return peer_write_message(conn, &peer->pcs, take(initmsg), read_init);
}
static int make_listen_fd(int domain, void *addr, socklen_t len, bool mayfail)
{
int fd = socket(domain, SOCK_STREAM, 0);
if (fd < 0) {
if (!mayfail)
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed to create %u socket: %s",
domain, strerror(errno));
status_trace("Failed to create %u socket: %s",
domain, strerror(errno));
return -1;
}
if (addr) {
int on = 1;
/* Re-use, please.. */
if (setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)))
status_unusual("Failed setting socket reuse: %s",
strerror(errno));
if (bind(fd, addr, len) != 0) {
if (!mayfail)
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed to bind on %u socket: %s",
domain, strerror(errno));
status_trace("Failed to create %u socket: %s",
domain, strerror(errno));
goto fail;
}
}
return fd;
fail:
close_noerr(fd);
return -1;
}
static struct io_plan *handshake_in_success(struct io_conn *conn,
const struct pubkey *id,
const struct wireaddr_internal *addr,
const struct crypto_state *cs,
struct daemon *daemon)
{
status_trace("Connect IN from %s",
type_to_string(tmpctx, struct pubkey, id));
return init_new_peer(conn, id, addr, cs, daemon);
}
static struct io_plan *connection_in(struct io_conn *conn, struct daemon *daemon)
{
struct wireaddr_internal addr;
struct sockaddr_storage s = {};
socklen_t len = sizeof(s);
if (getpeername(io_conn_fd(conn), (struct sockaddr *)&s, &len) != 0) {
status_trace("Failed to get peername for incoming conn: %s",
strerror(errno));
return io_close(conn);
}
if (s.ss_family == AF_INET6) {
struct sockaddr_in6 *s6 = (void *)&s;
addr.itype = ADDR_INTERNAL_WIREADDR;
wireaddr_from_ipv6(&addr.u.wireaddr,
&s6->sin6_addr, ntohs(s6->sin6_port));
} else if (s.ss_family == AF_INET) {
struct sockaddr_in *s4 = (void *)&s;
addr.itype = ADDR_INTERNAL_WIREADDR;
wireaddr_from_ipv4(&addr.u.wireaddr,
&s4->sin_addr, ntohs(s4->sin_port));
} else if (s.ss_family == AF_UNIX) {
struct sockaddr_un *sun = (void *)&s;
addr.itype = ADDR_INTERNAL_SOCKNAME;
memcpy(addr.u.sockname, sun->sun_path, sizeof(sun->sun_path));
} else {
status_broken("Unknown socket type %i for incoming conn",
s.ss_family);
return io_close(conn);
}
/* FIXME: Timeout */
return responder_handshake(conn, &daemon->id, &addr,
handshake_in_success, daemon);
}
static void add_listen_fd(struct daemon *daemon, int fd, bool mayfail)
{
size_t n = tal_count(daemon->listen_fds);
tal_resize(&daemon->listen_fds, n+1);
daemon->listen_fds[n].fd = fd;
daemon->listen_fds[n].mayfail = mayfail;
}
/* Return true if it created socket successfully. */
static bool handle_wireaddr_listen(struct daemon *daemon,
const struct wireaddr *wireaddr,
bool mayfail)
{
int fd;
struct sockaddr_in addr;
struct sockaddr_in6 addr6;
switch (wireaddr->type) {
case ADDR_TYPE_IPV4:
wireaddr_to_ipv4(wireaddr, &addr);
/* We might fail if IPv6 bound to port first */
fd = make_listen_fd(AF_INET, &addr, sizeof(addr), mayfail);
if (fd >= 0) {
status_trace("Created IPv4 listener on port %u",
wireaddr->port);
add_listen_fd(daemon, fd, mayfail);
return true;
}
return false;
case ADDR_TYPE_IPV6:
wireaddr_to_ipv6(wireaddr, &addr6);
fd = make_listen_fd(AF_INET6, &addr6, sizeof(addr6), mayfail);
if (fd >= 0) {
status_trace("Created IPv6 listener on port %u",
wireaddr->port);
add_listen_fd(daemon, fd, mayfail);
return true;
}
return false;
case ADDR_TYPE_PADDING:
case ADDR_TYPE_TOR_V2:
case ADDR_TYPE_TOR_V3:
break;
}
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Invalid listener wireaddress type %u", wireaddr->type);
}
/* If it's a wildcard, turns it into a real address pointing to internet */
static bool public_address(struct daemon *daemon, struct wireaddr *wireaddr)
{
if (wireaddr_is_wildcard(wireaddr)) {
if (!guess_address(wireaddr))
return false;
}
return address_routable(wireaddr, daemon->dev_allow_localhost);
}
static void add_announcable(struct wireaddr **announcable,
const struct wireaddr *addr)
{
size_t n = tal_count(*announcable);
tal_resize(announcable, n+1);
(*announcable)[n] = *addr;
}
static void add_binding(struct wireaddr_internal **binding,
const struct wireaddr_internal *addr)
{
size_t n = tal_count(*binding);
tal_resize(binding, n+1);
(*binding)[n] = *addr;
}
static int wireaddr_cmp_type(const struct wireaddr *a,
const struct wireaddr *b, void *unused)
{
return (int)a->type - (int)b->type;
}
static void finalize_announcable(struct wireaddr **announcable)
{
size_t n = tal_count(*announcable);
/* BOLT #7:
*
* The origin node:
*...
* - MUST place non-zero typed address descriptors in ascending order.
*...
* - MUST NOT include more than one `address descriptor` of the same
* type.
*/
asort(*announcable, n, wireaddr_cmp_type, NULL);
for (size_t i = 1; i < n; i++) {
/* Note we use > instead of !=: catches asort bugs too. */
if ((*announcable)[i].type > (*announcable)[i-1].type)
continue;
status_unusual("WARNING: Cannot announce address %s,"
" already announcing %s",
type_to_string(tmpctx, struct wireaddr,
&(*announcable)[i]),
type_to_string(tmpctx, struct wireaddr,
&(*announcable)[i-1]));
memmove(*announcable + i,
*announcable + i + 1,
(n - i - 1) * sizeof((*announcable)[0]));
tal_resize(announcable, --n);
--i;
}
}
/* Initializes daemon->announcable array, returns addresses we bound to. */
static struct wireaddr_internal *setup_listeners(const tal_t *ctx,
struct daemon *daemon,
const struct wireaddr_internal *proposed_wireaddr,
const enum addr_listen_announce *proposed_listen_announce,
const char *tor_password,
struct wireaddr **announcable)
{
struct sockaddr_un addrun;
int fd;
struct wireaddr_internal *binding;
binding = tal_arr(ctx, struct wireaddr_internal, 0);
*announcable = tal_arr(ctx, struct wireaddr, 0);
/* Add addresses we've explicitly been told to *first*: implicit
* addresses will be discarded then if we have multiple. */
for (size_t i = 0; i < tal_count(proposed_wireaddr); i++) {
struct wireaddr_internal wa = proposed_wireaddr[i];
if (proposed_listen_announce[i] & ADDR_LISTEN)
continue;
assert(proposed_listen_announce[i] & ADDR_ANNOUNCE);
/* You can only announce wiretypes! */
assert(proposed_wireaddr[i].itype
== ADDR_INTERNAL_WIREADDR);
add_announcable(announcable, &wa.u.wireaddr);
}
/* Now look for listening addresses. */
for (size_t i = 0; i < tal_count(proposed_wireaddr); i++) {
struct wireaddr_internal wa = proposed_wireaddr[i];
bool announce = (proposed_listen_announce[i] & ADDR_ANNOUNCE);
if (!(proposed_listen_announce[i] & ADDR_LISTEN))
continue;
switch (wa.itype) {
case ADDR_INTERNAL_SOCKNAME:
addrun.sun_family = AF_UNIX;
memcpy(addrun.sun_path, wa.u.sockname,
sizeof(addrun.sun_path));
fd = make_listen_fd(AF_INET, &addrun, sizeof(addrun),
false);
status_trace("Created socket listener on file %s",
addrun.sun_path);
add_listen_fd(daemon, fd, false);
/* We don't announce socket names */
assert(!announce);
add_binding(&binding, &wa);
continue;
case ADDR_INTERNAL_AUTOTOR:
/* We handle these after we have all bindings. */
continue;
case ADDR_INTERNAL_ALLPROTO: {
bool ipv6_ok;
wa.itype = ADDR_INTERNAL_WIREADDR;
wa.u.wireaddr.port = wa.u.port;
/* First, create wildcard IPv6 address. */
wa.u.wireaddr.type = ADDR_TYPE_IPV6;
wa.u.wireaddr.addrlen = 16;
memset(wa.u.wireaddr.addr, 0,
sizeof(wa.u.wireaddr.addr));
ipv6_ok = handle_wireaddr_listen(daemon, &wa.u.wireaddr,
true);
if (ipv6_ok) {
add_binding(&binding, &wa);
if (announce
&& public_address(daemon, &wa.u.wireaddr))
add_announcable(announcable,
&wa.u.wireaddr);
}
/* Now, create wildcard IPv4 address. */
wa.u.wireaddr.type = ADDR_TYPE_IPV4;
wa.u.wireaddr.addrlen = 4;
memset(wa.u.wireaddr.addr, 0,
sizeof(wa.u.wireaddr.addr));
/* OK if this fails, as long as one succeeds! */
if (handle_wireaddr_listen(daemon, &wa.u.wireaddr,
ipv6_ok)) {
add_binding(&binding, &wa);
if (announce
&& public_address(daemon, &wa.u.wireaddr))
add_announcable(announcable,
&wa.u.wireaddr);
}
continue;
}
case ADDR_INTERNAL_WIREADDR:
handle_wireaddr_listen(daemon, &wa.u.wireaddr, false);
add_binding(&binding, &wa);
if (announce && public_address(daemon, &wa.u.wireaddr))
add_announcable(announcable, &wa.u.wireaddr);
continue;
case ADDR_INTERNAL_FORPROXY:
break;
}
/* Shouldn't happen. */
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Invalid listener address type %u",
proposed_wireaddr[i].itype);
}
/* Now we have bindings, set up any Tor auto addresses */
for (size_t i = 0; i < tal_count(proposed_wireaddr); i++) {
if (!(proposed_listen_announce[i] & ADDR_LISTEN))
continue;
if (!(proposed_listen_announce[i] & ADDR_ANNOUNCE))
continue;
if (proposed_wireaddr[i].itype != ADDR_INTERNAL_AUTOTOR)
continue;
add_announcable(announcable,
tor_autoservice(tmpctx,
&proposed_wireaddr[i].u.torservice,
tor_password,
binding));
}
finalize_announcable(announcable);
return binding;
}
/* Parse an incoming connect init message and assign config variables
* to the daemon.
*/
static struct io_plan *connect_init(struct daemon_conn *master,
struct daemon *daemon,
const u8 *msg)
{
struct wireaddr *proxyaddr;
struct wireaddr_internal *binding;
struct wireaddr_internal *proposed_wireaddr;
enum addr_listen_announce *proposed_listen_announce;
struct wireaddr *announcable;
char *tor_password;
if (!fromwire_connectctl_init(
daemon, msg,
&daemon->id, &daemon->globalfeatures,
&daemon->localfeatures, &proposed_wireaddr,
&proposed_listen_announce,
&proxyaddr, &daemon->use_proxy_always,
&daemon->dev_allow_localhost, &daemon->use_dns,
&tor_password)) {
master_badmsg(WIRE_CONNECTCTL_INIT, msg);
}
/* Resolve Tor proxy address if any */
if (proxyaddr) {
status_trace("Proxy address: %s",
fmt_wireaddr(tmpctx, proxyaddr));
daemon->proxyaddr = wireaddr_to_addrinfo(daemon, proxyaddr);
} else
daemon->proxyaddr = NULL;
if (broken_resolver(daemon)) {
status_trace("Broken DNS resolver detected, will check for "
"dummy replies");
}
binding = setup_listeners(tmpctx, daemon,
proposed_wireaddr,
proposed_listen_announce,
tor_password,
&announcable);
daemon_conn_send(&daemon->master,
take(towire_connectctl_init_reply(NULL,
binding,
announcable)));
return daemon_conn_read_next(master->conn, master);
}
static struct io_plan *connect_activate(struct daemon_conn *master,
struct daemon *daemon,
const u8 *msg)
{
bool do_listen;
if (!fromwire_connectctl_activate(msg, &do_listen))
master_badmsg(WIRE_CONNECTCTL_ACTIVATE, msg);
if (do_listen) {
for (size_t i = 0; i < tal_count(daemon->listen_fds); i++) {
/* On Linux, at least, we may bind to all addresses
* for IPv4 and IPv6, but we'll fail to listen. */
if (listen(daemon->listen_fds[i].fd, 5) != 0) {
if (daemon->listen_fds[i].mayfail)
continue;
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed to listen on socket: %s",
strerror(errno));
}
io_new_listener(daemon, daemon->listen_fds[i].fd,
connection_in, daemon);
}
}
daemon->listen_fds = tal_free(daemon->listen_fds);
/* OK, we're ready! */
daemon_conn_send(&daemon->master,
take(towire_connectctl_activate_reply(NULL)));
return daemon_conn_read_next(master->conn, master);
}
static struct io_plan *handshake_out_success(struct io_conn *conn,
const struct pubkey *id,
const struct wireaddr_internal *addr,
const struct crypto_state *cs,
struct reaching *reach)
{
reach->connstate = "Exchanging init messages";
status_trace("Connect OUT to %s",
type_to_string(tmpctx, struct pubkey, id));
return init_new_peer(conn, id, addr, cs, reach->daemon);
}
struct io_plan *connection_out(struct io_conn *conn, struct reaching *reach)
{
/* FIXME: Timeout */
status_trace("Connected out for %s",
type_to_string(tmpctx, struct pubkey, &reach->id));
reach->connstate = "Cryptographic handshake";
return initiator_handshake(conn, &reach->daemon->id, &reach->id,
&reach->addrs[reach->addrnum],
handshake_out_success, reach);
}
static void PRINTF_FMT(5,6)
connect_failed(struct daemon *daemon,
const struct pubkey *id,
u32 seconds_waited,
const struct wireaddr_internal *addrhint,
const char *errfmt, ...)
{
u8 *msg;
va_list ap;
char *err;
u32 wait_seconds;
va_start(ap, errfmt);
err = tal_vfmt(tmpctx, errfmt, ap);
va_end(ap);
/* Wait twice as long to reconnect, between min and max. */
wait_seconds = seconds_waited * 2;
if (wait_seconds > MAX_WAIT_SECONDS)
wait_seconds = MAX_WAIT_SECONDS;
if (wait_seconds < INITIAL_WAIT_SECONDS)
wait_seconds = INITIAL_WAIT_SECONDS;
/* Tell any connect command what happened. */
msg = towire_connectctl_connect_failed(NULL, id, err, wait_seconds,
addrhint);
daemon_conn_send(&daemon->master, take(msg));
status_trace("Failed connected out for %s: %s",
type_to_string(tmpctx, struct pubkey, id),
err);
}
static void destroy_io_conn(struct io_conn *conn, struct reaching *reach)
{
tal_append_fmt(&reach->errors,
"%s: %s: %s. ",
type_to_string(tmpctx, struct wireaddr_internal,
&reach->addrs[reach->addrnum]),
reach->connstate, strerror(errno));
reach->addrnum++;
try_reach_one_addr(reach);
}
static struct io_plan *conn_init(struct io_conn *conn, struct reaching *reach)
{
struct addrinfo *ai = NULL;
const struct wireaddr_internal *addr = &reach->addrs[reach->addrnum];
switch (addr->itype) {
case ADDR_INTERNAL_SOCKNAME:
ai = wireaddr_internal_to_addrinfo(tmpctx, addr);
break;
case ADDR_INTERNAL_ALLPROTO:
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach to all protocols");
break;
case ADDR_INTERNAL_AUTOTOR:
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach to autotor address");
break;
case ADDR_INTERNAL_FORPROXY:
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach to forproxy address");
break;
case ADDR_INTERNAL_WIREADDR:
/* If it was a Tor address, we wouldn't be here. */
ai = wireaddr_to_addrinfo(tmpctx, &addr->u.wireaddr);
break;
}
assert(ai);
io_set_finish(conn, destroy_io_conn, reach);
return io_connect(conn, ai, connection_out, reach);
}
static struct io_plan *conn_proxy_init(struct io_conn *conn,
struct reaching *reach)
{
const char *host = NULL;
u16 port;
const struct wireaddr_internal *addr = &reach->addrs[reach->addrnum];
switch (addr->itype) {
case ADDR_INTERNAL_FORPROXY:
host = addr->u.unresolved.name;
port = addr->u.unresolved.port;
break;
case ADDR_INTERNAL_WIREADDR:
host = fmt_wireaddr_without_port(tmpctx, &addr->u.wireaddr);
port = addr->u.wireaddr.port;
break;
case ADDR_INTERNAL_SOCKNAME:
case ADDR_INTERNAL_ALLPROTO:
case ADDR_INTERNAL_AUTOTOR:
break;
}
if (!host)
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach to %u address", addr->itype);
io_set_finish(conn, destroy_io_conn, reach);
return io_tor_connect(conn, reach->daemon->proxyaddr, host, port, reach);
}
static void append_addr(struct wireaddr_internal **addrs,
const struct wireaddr_internal *addr)
{
size_t n = tal_count(*addrs);
tal_resize(addrs, n+1);
(*addrs)[n] = *addr;
}
static const char *seedname(const tal_t *ctx, const struct pubkey *id)
{
char bech32[100];
u8 der[PUBKEY_DER_LEN];
u5 *data = tal_arr(ctx, u5, 0);
pubkey_to_der(der, id);
bech32_push_bits(&data, der, PUBKEY_DER_LEN*8);
bech32_encode(bech32, "ln", data, tal_count(data), sizeof(bech32));
return tal_fmt(ctx, "%s.lseed.bitcoinstats.com", bech32);
}
static void add_seed_addrs(struct wireaddr_internal **addrs,
const struct pubkey *id,
struct sockaddr *broken_reply)
{
struct wireaddr_internal a;
const char *addr;
addr = seedname(tmpctx, id);
status_trace("Resolving %s", addr);
a.itype = ADDR_INTERNAL_WIREADDR;
/* FIXME: wireaddr_from_hostname should return multiple addresses. */
if (!wireaddr_from_hostname(&a.u.wireaddr, addr, DEFAULT_PORT, NULL,
broken_reply, NULL)) {
status_trace("Could not resolve %s", addr);
} else {
status_trace("Resolved %s to %s", addr,
type_to_string(tmpctx, struct wireaddr,
&a.u.wireaddr));
append_addr(addrs, &a);
}
}
static void add_gossip_addrs(struct wireaddr_internal **addrs,
const struct pubkey *id)
{
u8 *msg;
struct wireaddr *normal_addrs;
msg = towire_gossip_get_addrs(NULL, id);
if (!wire_sync_write(GOSSIPCTL_FD, take(msg)))
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed writing to gossipctl: %s",
strerror(errno));
msg = wire_sync_read(tmpctx, GOSSIPCTL_FD);
if (!fromwire_gossip_get_addrs_reply(tmpctx, msg, &normal_addrs))
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Failed parsing get_addrs_reply gossipctl: %s",
tal_hex(tmpctx, msg));
/* Wrap each one in a wireaddr_internal and add to addrs. */
for (size_t i = 0; i < tal_count(normal_addrs); i++) {
struct wireaddr_internal addr;
addr.itype = ADDR_INTERNAL_WIREADDR;
addr.u.wireaddr = normal_addrs[i];
append_addr(addrs, &addr);
}
}
static void try_reach_one_addr(struct reaching *reach)
{
int fd, af;
bool use_proxy = reach->daemon->use_proxy_always;
const struct wireaddr_internal *addr = &reach->addrs[reach->addrnum];
if (reach->addrnum == tal_count(reach->addrs)) {
connect_failed(reach->daemon, &reach->id, reach->seconds_waited,
reach->addrhint, "%s", reach->errors);
tal_free(reach);
return;
}
/* Might not even be able to create eg. IPv6 sockets */
af = -1;
switch (addr->itype) {
case ADDR_INTERNAL_SOCKNAME:
af = AF_LOCAL;
/* Local sockets don't use tor proxy */
use_proxy = false;
break;
case ADDR_INTERNAL_ALLPROTO:
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach ALLPROTO");
case ADDR_INTERNAL_AUTOTOR:
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"Can't reach AUTOTOR");
case ADDR_INTERNAL_FORPROXY:
use_proxy = true;
break;
case ADDR_INTERNAL_WIREADDR:
switch (addr->u.wireaddr.type) {
case ADDR_TYPE_TOR_V2:
case ADDR_TYPE_TOR_V3:
use_proxy = true;
break;
case ADDR_TYPE_IPV4:
af = AF_INET;
break;
case ADDR_TYPE_IPV6:
af = AF_INET6;
break;
case ADDR_TYPE_PADDING:
break;
}
}
/* If we have to use proxy but we don't have one, we fail. */
if (use_proxy) {
if (!reach->daemon->proxyaddr) {
status_debug("Need proxy");
af = -1;
} else
af = reach->daemon->proxyaddr->ai_family;
}
if (af == -1) {
fd = -1;
errno = EPROTONOSUPPORT;
} else
fd = socket(af, SOCK_STREAM, 0);
if (fd < 0) {
tal_append_fmt(&reach->errors,
"%s: opening %i socket gave %s. ",
type_to_string(tmpctx, struct wireaddr_internal,
addr),
af, strerror(errno));
reach->addrnum++;
try_reach_one_addr(reach);
return;
}
if (use_proxy)
io_new_conn(reach, fd, conn_proxy_init, reach);
else
io_new_conn(reach, fd, conn_init, reach);
}
/* Consumes addrhint if not NULL */
static void try_reach_peer(struct daemon *daemon,
const struct pubkey *id,
u32 seconds_waited,
struct wireaddr_internal *addrhint)
{
struct wireaddr_internal *addrs;
bool use_proxy = daemon->use_proxy_always;
struct reaching *reach;
/* Already done? May happen with timer. */
if (pubkey_set_get(&daemon->peers, id))
return;
/* If we're trying to reach it right now, that's OK. */
if (find_reaching(daemon, id))
return;
addrs = tal_arr(tmpctx, struct wireaddr_internal, 0);
if (addrhint)
append_addr(&addrs, addrhint);
add_gossip_addrs(&addrs, id);
if (tal_count(addrs) == 0) {
/* Don't resolve via DNS seed if we're supposed to use proxy. */
if (use_proxy) {
struct wireaddr_internal unresolved;
wireaddr_from_unresolved(&unresolved,
seedname(tmpctx, id),
DEFAULT_PORT);
append_addr(&addrs, &unresolved);
} else if (daemon->use_dns) {
add_seed_addrs(&addrs, id,
daemon->broken_resolver_response);
}
}
if (tal_count(addrs) == 0) {
connect_failed(daemon, id, seconds_waited, addrhint,
"No address known");
return;
}
/* Start connecting to it */
reach = tal(daemon, struct reaching);
reach->daemon = daemon;
reach->id = *id;
reach->addrs = tal_steal(reach, addrs);
reach->addrnum = 0;
reach->connstate = "Connection establishment";
reach->seconds_waited = seconds_waited;
reach->addrhint = tal_steal(reach, addrhint);
reach->errors = tal_strdup(reach, "");
list_add_tail(&daemon->reaching, &reach->list);
tal_add_destructor(reach, destroy_reaching);
try_reach_one_addr(reach);
}
static struct io_plan *connect_to_peer(struct io_conn *conn,
struct daemon *daemon, const u8 *msg)
{
struct pubkey id;
u32 seconds_waited;
struct wireaddr_internal *addrhint;
if (!fromwire_connectctl_connect_to_peer(tmpctx, msg,
&id, &seconds_waited,
&addrhint))
master_badmsg(WIRE_CONNECTCTL_CONNECT_TO_PEER, msg);
try_reach_peer(daemon, &id, seconds_waited, addrhint);
return daemon_conn_read_next(conn, &daemon->master);
}
static struct io_plan *peer_disconnected(struct io_conn *conn,
struct daemon *daemon, const u8 *msg)
{
struct pubkey id, *key;
struct peer *peer;
if (!fromwire_connectctl_peer_disconnected(msg, &id))
master_badmsg(WIRE_CONNECTCTL_PEER_DISCONNECTED, msg);
key = pubkey_set_get(&daemon->peers, &id);
if (!key)
status_failed(STATUS_FAIL_INTERNAL_ERROR,
"peer_disconnected unknown peer: %s",
type_to_string(tmpctx, struct pubkey, &id));
pubkey_set_del(&daemon->peers, key);
tal_free(key);
status_trace("Forgetting peer %s",
type_to_string(tmpctx, struct pubkey, &id));
/* If there was a connecting peer waiting, wake it now */
peer = find_reconnecting_peer(daemon, &id);
if (peer)
io_wake(peer);
return daemon_conn_read_next(conn, &daemon->master);
}
static struct io_plan *recv_req(struct io_conn *conn, struct daemon_conn *master)
{
struct daemon *daemon = container_of(master, struct daemon, master);
enum connect_wire_type t = fromwire_peektype(master->msg_in);
switch (t) {
case WIRE_CONNECTCTL_INIT:
return connect_init(master, daemon, master->msg_in);
case WIRE_CONNECTCTL_ACTIVATE:
return connect_activate(master, daemon, master->msg_in);
case WIRE_CONNECTCTL_CONNECT_TO_PEER:
return connect_to_peer(conn, daemon, master->msg_in);
case WIRE_CONNECTCTL_PEER_DISCONNECTED:
return peer_disconnected(conn, daemon, master->msg_in);
/* We send these, we don't receive them */
case WIRE_CONNECTCTL_INIT_REPLY:
case WIRE_CONNECTCTL_ACTIVATE_REPLY:
case WIRE_CONNECT_PEER_CONNECTED:
case WIRE_CONNECT_RECONNECTED:
case WIRE_CONNECTCTL_CONNECT_FAILED:
break;
}
/* Master shouldn't give bad requests. */
status_failed(STATUS_FAIL_MASTER_IO, "%i: %s",
t, tal_hex(tmpctx, master->msg_in));
}
/* Helper for handshake.c */
bool hsm_do_ecdh(struct secret *ss, const struct pubkey *point)
{
u8 *req = towire_hsm_ecdh_req(tmpctx, point), *resp;
if (!wire_sync_write(HSM_FD, req))
return false;
resp = wire_sync_read(req, HSM_FD);
if (!resp)
return false;
if (!fromwire_hsm_ecdh_resp(resp, ss))
return false;
return true;
}
#ifndef TESTING
static void master_gone(struct io_conn *unused UNUSED, struct daemon_conn *dc UNUSED)
{
/* Can't tell master, it's gone. */
exit(2);
}
int main(int argc, char *argv[])
{
setup_locale();
struct daemon *daemon;
subdaemon_setup(argc, argv);
daemon = tal(NULL, struct daemon);
pubkey_set_init(&daemon->peers);
list_head_init(&daemon->reconnecting);
list_head_init(&daemon->reaching);
timers_init(&daemon->timers, time_mono());
daemon->broken_resolver_response = NULL;
daemon->listen_fds = tal_arr(daemon, struct listen_fd, 0);
/* stdin == control */
daemon_conn_init(daemon, &daemon->master, STDIN_FILENO, recv_req,
master_gone);
status_setup_async(&daemon->master);
/* When conn closes, everything is freed. */
tal_steal(daemon->master.conn, daemon);
for (;;) {
struct timer *expired = NULL;
io_loop(&daemon->timers, &expired);
if (!expired) {
break;
} else {
timer_expired(daemon, expired);
}
}
daemon_shutdown();
return 0;
}
#endif