/*************************************************************************** * _ _ ____ _ * Project ___| | | | _ \| | * / __| | | | |_) | | * | (__| |_| | _ <| |___ * \___|\___/|_| \_\_____| * * Copyright (C) 1998 - 2019, Daniel Stenberg, , et al. * * This software is licensed as described in the file COPYING, which * you should have received as part of this distribution. The terms * are also available at https://curl.haxx.se/docs/copyright.html. * * You may opt to use, copy, modify, merge, publish, distribute and/or sell * copies of the Software, and permit persons to whom the Software is * furnished to do so, under the terms of the COPYING file. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ***************************************************************************/ #include "curl_setup.h" /*********************************************************************** * Only for threaded name resolves builds **********************************************************************/ #ifdef CURLRES_THREADED #ifdef HAVE_NETINET_IN_H #include #endif #ifdef HAVE_NETDB_H #include #endif #ifdef HAVE_ARPA_INET_H #include #endif #ifdef __VMS #include #include #endif #if defined(USE_THREADS_POSIX) # ifdef HAVE_PTHREAD_H # include # endif #elif defined(USE_THREADS_WIN32) # ifdef HAVE_PROCESS_H # include # endif #endif #if (defined(NETWARE) && defined(__NOVELL_LIBC__)) #undef in_addr_t #define in_addr_t unsigned long #endif #ifdef HAVE_GETADDRINFO # define RESOLVER_ENOMEM EAI_MEMORY #else # define RESOLVER_ENOMEM ENOMEM #endif #include "urldata.h" #include "sendf.h" #include "hostip.h" #include "hash.h" #include "share.h" #include "strerror.h" #include "url.h" #include "multiif.h" #include "inet_pton.h" #include "inet_ntop.h" #include "curl_threads.h" #include "connect.h" /* The last 3 #include files should be in this order */ #include "curl_printf.h" #include "curl_memory.h" #include "memdebug.h" struct resdata { struct curltime start; }; /* * Curl_resolver_global_init() * Called from curl_global_init() to initialize global resolver environment. * Does nothing here. */ int Curl_resolver_global_init(void) { return CURLE_OK; } /* * Curl_resolver_global_cleanup() * Called from curl_global_cleanup() to destroy global resolver environment. * Does nothing here. */ void Curl_resolver_global_cleanup(void) { } /* * Curl_resolver_init() * Called from curl_easy_init() -> Curl_open() to initialize resolver * URL-state specific environment ('resolver' member of the UrlState * structure). */ CURLcode Curl_resolver_init(struct Curl_easy *easy, void **resolver) { (void)easy; *resolver = calloc(1, sizeof(struct resdata)); if(!*resolver) return CURLE_OUT_OF_MEMORY; return CURLE_OK; } /* * Curl_resolver_cleanup() * Called from curl_easy_cleanup() -> Curl_close() to cleanup resolver * URL-state specific environment ('resolver' member of the UrlState * structure). */ void Curl_resolver_cleanup(void *resolver) { free(resolver); } /* * Curl_resolver_duphandle() * Called from curl_easy_duphandle() to duplicate resolver URL state-specific * environment ('resolver' member of the UrlState structure). */ CURLcode Curl_resolver_duphandle(struct Curl_easy *easy, void **to, void *from) { (void)from; return Curl_resolver_init(easy, to); } static void destroy_async_data(struct Curl_async *); /* * Cancel all possibly still on-going resolves for this connection. */ void Curl_resolver_cancel(struct connectdata *conn) { destroy_async_data(&conn->async); } /* This function is used to init a threaded resolve */ static bool init_resolve_thread(struct connectdata *conn, const char *hostname, int port, const struct addrinfo *hints); /* Data for synchronization between resolver thread and its parent */ struct thread_sync_data { curl_mutex_t * mtx; int done; char *hostname; /* hostname to resolve, Curl_async.hostname duplicate */ int port; #ifdef HAVE_SOCKETPAIR curl_socket_t sock_pair[2]; /* socket pair */ #endif int sock_error; Curl_addrinfo *res; #ifdef HAVE_GETADDRINFO struct addrinfo hints; #endif struct thread_data *td; /* for thread-self cleanup */ }; struct thread_data { curl_thread_t thread_hnd; unsigned int poll_interval; time_t interval_end; struct thread_sync_data tsd; }; static struct thread_sync_data *conn_thread_sync_data(struct connectdata *conn) { return &(((struct thread_data *)conn->async.os_specific)->tsd); } /* Destroy resolver thread synchronization data */ static void destroy_thread_sync_data(struct thread_sync_data * tsd) { if(tsd->mtx) { Curl_mutex_destroy(tsd->mtx); free(tsd->mtx); } free(tsd->hostname); if(tsd->res) Curl_freeaddrinfo(tsd->res); #ifdef HAVE_SOCKETPAIR /* close socket pair */ if(tsd->sock_pair[0] != CURL_SOCKET_BAD) { sclose(tsd->sock_pair[0]); } if(tsd->sock_pair[1] != CURL_SOCKET_BAD) { sclose(tsd->sock_pair[1]); } #endif memset(tsd, 0, sizeof(*tsd)); } /* Initialize resolver thread synchronization data */ static int init_thread_sync_data(struct thread_data * td, const char *hostname, int port, const struct addrinfo *hints) { struct thread_sync_data *tsd = &td->tsd; memset(tsd, 0, sizeof(*tsd)); tsd->td = td; tsd->port = port; /* Treat the request as done until the thread actually starts so any early * cleanup gets done properly. */ tsd->done = 1; #ifdef HAVE_GETADDRINFO DEBUGASSERT(hints); tsd->hints = *hints; #else (void) hints; #endif tsd->mtx = malloc(sizeof(curl_mutex_t)); if(tsd->mtx == NULL) goto err_exit; Curl_mutex_init(tsd->mtx); #ifdef HAVE_SOCKETPAIR /* create socket pair */ if(socketpair(AF_LOCAL, SOCK_STREAM, 0, &tsd->sock_pair[0]) < 0) { tsd->sock_pair[0] = CURL_SOCKET_BAD; tsd->sock_pair[1] = CURL_SOCKET_BAD; goto err_exit; } #endif tsd->sock_error = CURL_ASYNC_SUCCESS; /* Copying hostname string because original can be destroyed by parent * thread during gethostbyname execution. */ tsd->hostname = strdup(hostname); if(!tsd->hostname) goto err_exit; return 1; err_exit: /* Memory allocation failed */ destroy_thread_sync_data(tsd); return 0; } static int getaddrinfo_complete(struct connectdata *conn) { struct thread_sync_data *tsd = conn_thread_sync_data(conn); int rc; rc = Curl_addrinfo_callback(conn, tsd->sock_error, tsd->res); /* The tsd->res structure has been copied to async.dns and perhaps the DNS cache. Set our copy to NULL so destroy_thread_sync_data doesn't free it. */ tsd->res = NULL; return rc; } #ifdef HAVE_GETADDRINFO /* * getaddrinfo_thread() resolves a name and then exits. * * For builds without ARES, but with ENABLE_IPV6, create a resolver thread * and wait on it. */ static unsigned int CURL_STDCALL getaddrinfo_thread(void *arg) { struct thread_sync_data *tsd = (struct thread_sync_data*)arg; struct thread_data *td = tsd->td; char service[12]; int rc; #ifdef HAVE_SOCKETPAIR char buf[1]; #endif msnprintf(service, sizeof(service), "%d", tsd->port); rc = Curl_getaddrinfo_ex(tsd->hostname, service, &tsd->hints, &tsd->res); if(rc != 0) { tsd->sock_error = SOCKERRNO?SOCKERRNO:rc; if(tsd->sock_error == 0) tsd->sock_error = RESOLVER_ENOMEM; } else { Curl_addrinfo_set_port(tsd->res, tsd->port); } Curl_mutex_acquire(tsd->mtx); if(tsd->done) { /* too late, gotta clean up the mess */ Curl_mutex_release(tsd->mtx); destroy_thread_sync_data(tsd); free(td); } else { #ifdef HAVE_SOCKETPAIR if(tsd->sock_pair[1] != CURL_SOCKET_BAD) { /* DNS has been resolved, signal client task */ buf[0] = 1; if(write(tsd->sock_pair[1], buf, sizeof(buf)) < 0) { /* update sock_erro to errno */ tsd->sock_error = SOCKERRNO; } } #endif tsd->done = 1; Curl_mutex_release(tsd->mtx); } return 0; } #else /* HAVE_GETADDRINFO */ /* * gethostbyname_thread() resolves a name and then exits. */ static unsigned int CURL_STDCALL gethostbyname_thread(void *arg) { struct thread_sync_data *tsd = (struct thread_sync_data *)arg; struct thread_data *td = tsd->td; tsd->res = Curl_ipv4_resolve_r(tsd->hostname, tsd->port); if(!tsd->res) { tsd->sock_error = SOCKERRNO; if(tsd->sock_error == 0) tsd->sock_error = RESOLVER_ENOMEM; } Curl_mutex_acquire(tsd->mtx); if(tsd->done) { /* too late, gotta clean up the mess */ Curl_mutex_release(tsd->mtx); destroy_thread_sync_data(tsd); free(td); } else { tsd->done = 1; Curl_mutex_release(tsd->mtx); } return 0; } #endif /* HAVE_GETADDRINFO */ /* * destroy_async_data() cleans up async resolver data and thread handle. */ static void destroy_async_data(struct Curl_async *async) { if(async->os_specific) { struct thread_data *td = (struct thread_data*) async->os_specific; int done; /* * if the thread is still blocking in the resolve syscall, detach it and * let the thread do the cleanup... */ Curl_mutex_acquire(td->tsd.mtx); done = td->tsd.done; td->tsd.done = 1; Curl_mutex_release(td->tsd.mtx); if(!done) { Curl_thread_destroy(td->thread_hnd); } else { if(td->thread_hnd != curl_thread_t_null) Curl_thread_join(&td->thread_hnd); destroy_thread_sync_data(&td->tsd); free(async->os_specific); } } async->os_specific = NULL; free(async->hostname); async->hostname = NULL; } /* * init_resolve_thread() starts a new thread that performs the actual * resolve. This function returns before the resolve is done. * * Returns FALSE in case of failure, otherwise TRUE. */ static bool init_resolve_thread(struct connectdata *conn, const char *hostname, int port, const struct addrinfo *hints) { struct thread_data *td = calloc(1, sizeof(struct thread_data)); int err = ENOMEM; conn->async.os_specific = (void *)td; if(!td) goto errno_exit; conn->async.port = port; conn->async.done = FALSE; conn->async.status = 0; conn->async.dns = NULL; td->thread_hnd = curl_thread_t_null; if(!init_thread_sync_data(td, hostname, port, hints)) { conn->async.os_specific = NULL; free(td); goto errno_exit; } free(conn->async.hostname); conn->async.hostname = strdup(hostname); if(!conn->async.hostname) goto err_exit; /* The thread will set this to 1 when complete. */ td->tsd.done = 0; #ifdef HAVE_GETADDRINFO td->thread_hnd = Curl_thread_create(getaddrinfo_thread, &td->tsd); #else td->thread_hnd = Curl_thread_create(gethostbyname_thread, &td->tsd); #endif if(!td->thread_hnd) { /* The thread never started, so mark it as done here for proper cleanup. */ td->tsd.done = 1; err = errno; goto err_exit; } return TRUE; err_exit: destroy_async_data(&conn->async); errno_exit: errno = err; return FALSE; } /* * resolver_error() calls failf() with the appropriate message after a resolve * error */ static CURLcode resolver_error(struct connectdata *conn) { const char *host_or_proxy; CURLcode result; if(conn->bits.httpproxy) { host_or_proxy = "proxy"; result = CURLE_COULDNT_RESOLVE_PROXY; } else { host_or_proxy = "host"; result = CURLE_COULDNT_RESOLVE_HOST; } failf(conn->data, "Could not resolve %s: %s", host_or_proxy, conn->async.hostname); return result; } static CURLcode thread_wait_resolv(struct connectdata *conn, struct Curl_dns_entry **entry, bool report) { struct thread_data *td = (struct thread_data*) conn->async.os_specific; CURLcode result = CURLE_OK; DEBUGASSERT(conn && td); DEBUGASSERT(td->thread_hnd != curl_thread_t_null); /* wait for the thread to resolve the name */ if(Curl_thread_join(&td->thread_hnd)) { if(entry) result = getaddrinfo_complete(conn); } else DEBUGASSERT(0); conn->async.done = TRUE; if(entry) *entry = conn->async.dns; if(!conn->async.dns && report) /* a name was not resolved, report error */ result = resolver_error(conn); destroy_async_data(&conn->async); if(!conn->async.dns && report) connclose(conn, "asynch resolve failed"); return result; } /* * Until we gain a way to signal the resolver threads to stop early, we must * simply wait for them and ignore their results. */ void Curl_resolver_kill(struct connectdata *conn) { struct thread_data *td = (struct thread_data*) conn->async.os_specific; /* If we're still resolving, we must wait for the threads to fully clean up, unfortunately. Otherwise, we can simply cancel to clean up any resolver data. */ if(td && td->thread_hnd != curl_thread_t_null) (void)thread_wait_resolv(conn, NULL, FALSE); else Curl_resolver_cancel(conn); } /* * Curl_resolver_wait_resolv() * * Waits for a resolve to finish. This function should be avoided since using * this risk getting the multi interface to "hang". * * If 'entry' is non-NULL, make it point to the resolved dns entry * * Returns CURLE_COULDNT_RESOLVE_HOST if the host was not resolved, * CURLE_OPERATION_TIMEDOUT if a time-out occurred, or other errors. * * This is the version for resolves-in-a-thread. */ CURLcode Curl_resolver_wait_resolv(struct connectdata *conn, struct Curl_dns_entry **entry) { return thread_wait_resolv(conn, entry, TRUE); } /* * Curl_resolver_is_resolved() is called repeatedly to check if a previous * name resolve request has completed. It should also make sure to time-out if * the operation seems to take too long. */ CURLcode Curl_resolver_is_resolved(struct connectdata *conn, struct Curl_dns_entry **entry) { struct Curl_easy *data = conn->data; struct thread_data *td = (struct thread_data*) conn->async.os_specific; int done = 0; *entry = NULL; if(!td) { DEBUGASSERT(td); return CURLE_COULDNT_RESOLVE_HOST; } Curl_mutex_acquire(td->tsd.mtx); done = td->tsd.done; Curl_mutex_release(td->tsd.mtx); if(done) { getaddrinfo_complete(conn); if(!conn->async.dns) { CURLcode result = resolver_error(conn); destroy_async_data(&conn->async); return result; } destroy_async_data(&conn->async); *entry = conn->async.dns; } else { /* poll for name lookup done with exponential backoff up to 250ms */ /* should be fine even if this converts to 32 bit */ time_t elapsed = (time_t)Curl_timediff(Curl_now(), data->progress.t_startsingle); if(elapsed < 0) elapsed = 0; if(td->poll_interval == 0) /* Start at 1ms poll interval */ td->poll_interval = 1; else if(elapsed >= td->interval_end) /* Back-off exponentially if last interval expired */ td->poll_interval *= 2; if(td->poll_interval > 250) td->poll_interval = 250; td->interval_end = elapsed + td->poll_interval; Curl_expire(conn->data, td->poll_interval, EXPIRE_ASYNC_NAME); } return CURLE_OK; } int Curl_resolver_getsock(struct connectdata *conn, curl_socket_t *socks) { int ret_val = 0; time_t milli; timediff_t ms; struct Curl_easy *data = conn->data; struct resdata *reslv = (struct resdata *)data->state.resolver; #ifdef HAVE_SOCKETPAIR struct thread_data *td = (struct thread_data*)conn->async.os_specific; #else (void)socks; #endif #ifdef HAVE_SOCKETPAIR if(td) { /* return read fd to client for polling the DNS resolution status */ socks[0] = td->tsd.sock_pair[0]; ret_val = GETSOCK_READSOCK(0); } else { #endif ms = Curl_timediff(Curl_now(), reslv->start); if(ms < 3) milli = 0; else if(ms <= 50) milli = (time_t)ms/3; else if(ms <= 250) milli = 50; else milli = 200; Curl_expire(data, milli, EXPIRE_ASYNC_NAME); #ifdef HAVE_SOCKETPAIR } #endif return ret_val; } #ifndef HAVE_GETADDRINFO /* * Curl_getaddrinfo() - for platforms without getaddrinfo */ Curl_addrinfo *Curl_resolver_getaddrinfo(struct connectdata *conn, const char *hostname, int port, int *waitp) { struct in_addr in; struct Curl_easy *data = conn->data; struct resdata *reslv = (struct resdata *)data->state.resolver; *waitp = 0; /* default to synchronous response */ if(Curl_inet_pton(AF_INET, hostname, &in) > 0) /* This is a dotted IP address 123.123.123.123-style */ return Curl_ip2addr(AF_INET, &in, hostname, port); reslv->start = Curl_now(); /* fire up a new resolver thread! */ if(init_resolve_thread(conn, hostname, port, NULL)) { *waitp = 1; /* expect asynchronous response */ return NULL; } failf(conn->data, "getaddrinfo() thread failed\n"); return NULL; } #else /* !HAVE_GETADDRINFO */ /* * Curl_resolver_getaddrinfo() - for getaddrinfo */ Curl_addrinfo *Curl_resolver_getaddrinfo(struct connectdata *conn, const char *hostname, int port, int *waitp) { struct addrinfo hints; char sbuf[12]; int pf = PF_INET; struct Curl_easy *data = conn->data; struct resdata *reslv = (struct resdata *)data->state.resolver; *waitp = 0; /* default to synchronous response */ #ifndef USE_RESOLVE_ON_IPS { struct in_addr in; /* First check if this is an IPv4 address string */ if(Curl_inet_pton(AF_INET, hostname, &in) > 0) /* This is a dotted IP address 123.123.123.123-style */ return Curl_ip2addr(AF_INET, &in, hostname, port); } #ifdef CURLRES_IPV6 { struct in6_addr in6; /* check if this is an IPv6 address string */ if(Curl_inet_pton(AF_INET6, hostname, &in6) > 0) /* This is an IPv6 address literal */ return Curl_ip2addr(AF_INET6, &in6, hostname, port); } #endif /* CURLRES_IPV6 */ #endif /* !USE_RESOLVE_ON_IPS */ #ifdef CURLRES_IPV6 /* * Check if a limited name resolve has been requested. */ switch(conn->ip_version) { case CURL_IPRESOLVE_V4: pf = PF_INET; break; case CURL_IPRESOLVE_V6: pf = PF_INET6; break; default: pf = PF_UNSPEC; break; } if((pf != PF_INET) && !Curl_ipv6works()) /* The stack seems to be a non-IPv6 one */ pf = PF_INET; #endif /* CURLRES_IPV6 */ memset(&hints, 0, sizeof(hints)); hints.ai_family = pf; hints.ai_socktype = (conn->transport == TRNSPRT_TCP)? SOCK_STREAM : SOCK_DGRAM; msnprintf(sbuf, sizeof(sbuf), "%d", port); reslv->start = Curl_now(); /* fire up a new resolver thread! */ if(init_resolve_thread(conn, hostname, port, &hints)) { *waitp = 1; /* expect asynchronous response */ return NULL; } failf(data, "getaddrinfo() thread failed to start\n"); return NULL; } #endif /* !HAVE_GETADDRINFO */ CURLcode Curl_set_dns_servers(struct Curl_easy *data, char *servers) { (void)data; (void)servers; return CURLE_NOT_BUILT_IN; } CURLcode Curl_set_dns_interface(struct Curl_easy *data, const char *interf) { (void)data; (void)interf; return CURLE_NOT_BUILT_IN; } CURLcode Curl_set_dns_local_ip4(struct Curl_easy *data, const char *local_ip4) { (void)data; (void)local_ip4; return CURLE_NOT_BUILT_IN; } CURLcode Curl_set_dns_local_ip6(struct Curl_easy *data, const char *local_ip6) { (void)data; (void)local_ip6; return CURLE_NOT_BUILT_IN; } #endif /* CURLRES_THREADED */