/* * FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * Copyright (C) 2005-2015, Anthony Minessale II * * Version: MPL 1.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/F * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * * The Initial Developer of the Original Code is * Michael Jerris * Portions created by the Initial Developer are Copyright (C) * the Initial Developer. All Rights Reserved. * * Contributor(s): * * Michael Jerris * Eliot Gable * William King * * switch_apr.c -- apr wrappers and extensions * */ #include #ifndef WIN32 #include #endif #include "private/switch_core_pvt.h" /* apr headers*/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define APR_WANT_STDIO #define APR_WANT_STRFUNC #include #include #include #include /* apr_vformatter_buff_t definition*/ #include /* apr-util headers */ #include #include #if (defined(HAVE_LIBMD5) || defined(HAVE_LIBMD) || defined(HAVE_MD5INIT)) #include #elif defined(HAVE_LIBCRYPTO) #include #else #include #endif /* apr stubs */ SWITCH_DECLARE(int) switch_status_is_timeup(int status) { return APR_STATUS_IS_TIMEUP(status); } /* Memory Pools */ SWITCH_DECLARE(switch_thread_id_t) switch_thread_self(void) { #ifndef WIN32 return apr_os_thread_current(); #else return (switch_thread_id_t) (GetCurrentThreadId()); #endif } SWITCH_DECLARE(int) switch_thread_equal(switch_thread_id_t tid1, switch_thread_id_t tid2) { #ifdef WIN32 return (tid1 == tid2); #else return apr_os_thread_equal(tid1, tid2); #endif } SWITCH_DECLARE(unsigned int) switch_ci_hashfunc_default(const char *char_key, switch_ssize_t *klen) { unsigned int hash = 0; const unsigned char *key = (const unsigned char *) char_key; const unsigned char *p; apr_ssize_t i; if (*klen == APR_HASH_KEY_STRING) { for (p = key; *p; p++) { hash = hash * 33 + tolower(*p); } *klen = p - key; } else { for (p = key, i = *klen; i; i--, p++) { hash = hash * 33 + tolower(*p); } } return hash; } SWITCH_DECLARE(unsigned int) switch_hashfunc_default(const char *key, switch_ssize_t *klen) { return apr_hashfunc_default(key, klen); } /* string functions */ SWITCH_DECLARE(switch_status_t) switch_strftime(char *s, switch_size_t *retsize, switch_size_t max, const char *format, switch_time_exp_t *tm) { const char *p = format; if (!p) return SWITCH_STATUS_FALSE; while (*p) { if (*p == '%') { switch (*(++p)) { case 'C': case 'D': case 'r': case 'R': case 'T': case 'e': case 'a': case 'A': case 'b': case 'B': case 'c': case 'd': case 'H': case 'I': case 'j': case 'm': case 'M': case 'p': case 'S': case 'U': case 'w': case 'W': case 'x': case 'X': case 'y': case 'Y': case 'z': case 'Z': case '%': p++; continue; case '\0': default: return SWITCH_STATUS_FALSE; } } p++; } return apr_strftime(s, retsize, max, format, (apr_time_exp_t *) tm); } SWITCH_DECLARE(switch_status_t) switch_strftime_nocheck(char *s, switch_size_t *retsize, switch_size_t max, const char *format, switch_time_exp_t *tm) { return apr_strftime(s, retsize, max, format, (apr_time_exp_t *) tm); } SWITCH_DECLARE(int) switch_snprintf(char *buf, switch_size_t len, const char *format, ...) { va_list ap; int ret; va_start(ap, format); ret = apr_vsnprintf(buf, len, format, ap); va_end(ap); return ret; } SWITCH_DECLARE(int) switch_vsnprintf(char *buf, switch_size_t len, const char *format, va_list ap) { return apr_vsnprintf(buf, len, format, ap); } SWITCH_DECLARE(char *) switch_copy_string(char *dst, const char *src, switch_size_t dst_size) { if (!dst) return NULL; if (!src) { *dst = '\0'; return dst; } return apr_cpystrn(dst, src, dst_size); } /* thread read write lock functions */ SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_create(switch_thread_rwlock_t ** rwlock, switch_memory_pool_t *pool) { return apr_thread_rwlock_create(rwlock, pool); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_destroy(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_destroy(rwlock); } SWITCH_DECLARE(switch_memory_pool_t *) switch_thread_rwlock_pool_get(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_pool_get(rwlock); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_rdlock(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_rdlock(rwlock); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_tryrdlock(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_tryrdlock(rwlock); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_wrlock(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_wrlock(rwlock); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_trywrlock(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_trywrlock(rwlock); } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_trywrlock_timeout(switch_thread_rwlock_t *rwlock, int timeout) { int sanity = timeout * 2; while (sanity) { if (switch_thread_rwlock_trywrlock(rwlock) == SWITCH_STATUS_SUCCESS) { return SWITCH_STATUS_SUCCESS; } sanity--; switch_yield(500000); } return SWITCH_STATUS_FALSE; } SWITCH_DECLARE(switch_status_t) switch_thread_rwlock_unlock(switch_thread_rwlock_t *rwlock) { return apr_thread_rwlock_unlock(rwlock); } /* thread mutex functions */ SWITCH_DECLARE(switch_status_t) switch_mutex_init(switch_mutex_t ** lock, unsigned int flags, switch_memory_pool_t *pool) { #ifdef WIN32 /* Old version of APR misunderstands mutexes. On Windows, mutexes are cross-process. APR has no reason to not use critical sections instead of mutexes. */ if (flags == SWITCH_MUTEX_NESTED) flags = SWITCH_MUTEX_DEFAULT; #endif return apr_thread_mutex_create(lock, flags, pool); } SWITCH_DECLARE(switch_status_t) switch_mutex_destroy(switch_mutex_t *lock) { return apr_thread_mutex_destroy(lock); } SWITCH_DECLARE(switch_status_t) switch_mutex_lock(switch_mutex_t *lock) { return apr_thread_mutex_lock(lock); } SWITCH_DECLARE(switch_status_t) switch_mutex_unlock(switch_mutex_t *lock) { return apr_thread_mutex_unlock(lock); } SWITCH_DECLARE(switch_status_t) switch_mutex_trylock(switch_mutex_t *lock) { return apr_thread_mutex_trylock(lock); } /* time function stubs */ SWITCH_DECLARE(switch_time_t) switch_time_now(void) { #if defined(HAVE_CLOCK_GETTIME) && defined(SWITCH_USE_CLOCK_FUNCS) struct timespec ts; clock_gettime(CLOCK_REALTIME, &ts); return ts.tv_sec * APR_USEC_PER_SEC + (ts.tv_nsec / 1000); #else return (switch_time_t) apr_time_now(); #endif } SWITCH_DECLARE(switch_status_t) switch_time_exp_gmt_get(switch_time_t *result, switch_time_exp_t *input) { return apr_time_exp_gmt_get((apr_time_t *) result, (apr_time_exp_t *) input); } SWITCH_DECLARE(switch_status_t) switch_time_exp_get(switch_time_t *result, switch_time_exp_t *input) { return apr_time_exp_get((apr_time_t *) result, (apr_time_exp_t *) input); } SWITCH_DECLARE(switch_status_t) switch_time_exp_lt(switch_time_exp_t *result, switch_time_t input) { return apr_time_exp_lt((apr_time_exp_t *) result, input); } SWITCH_DECLARE(switch_status_t) switch_time_exp_tz(switch_time_exp_t *result, switch_time_t input, switch_int32_t offs) { return apr_time_exp_tz((apr_time_exp_t *) result, input, (apr_int32_t) offs); } SWITCH_DECLARE(switch_status_t) switch_time_exp_gmt(switch_time_exp_t *result, switch_time_t input) { return apr_time_exp_gmt((apr_time_exp_t *) result, input); } SWITCH_DECLARE(switch_status_t) switch_rfc822_date(char *date_str, switch_time_t t) { return apr_rfc822_date(date_str, t); } SWITCH_DECLARE(switch_time_t) switch_time_make(switch_time_t sec, int32_t usec) { return ((switch_time_t) (sec) * APR_USEC_PER_SEC + (switch_time_t) (usec)); } /* Thread condition locks */ SWITCH_DECLARE(switch_status_t) switch_thread_cond_create(switch_thread_cond_t ** cond, switch_memory_pool_t *pool) { return apr_thread_cond_create(cond, pool); } SWITCH_DECLARE(switch_status_t) switch_thread_cond_wait(switch_thread_cond_t *cond, switch_mutex_t *mutex) { return apr_thread_cond_wait(cond, mutex); } SWITCH_DECLARE(switch_status_t) switch_thread_cond_timedwait(switch_thread_cond_t *cond, switch_mutex_t *mutex, switch_interval_time_t timeout) { apr_status_t st = apr_thread_cond_timedwait(cond, mutex, timeout); if (st == APR_TIMEUP) { st = SWITCH_STATUS_TIMEOUT; } return st; } SWITCH_DECLARE(switch_status_t) switch_thread_cond_signal(switch_thread_cond_t *cond) { return apr_thread_cond_signal(cond); } SWITCH_DECLARE(switch_status_t) switch_thread_cond_broadcast(switch_thread_cond_t *cond) { return apr_thread_cond_broadcast(cond); } SWITCH_DECLARE(switch_status_t) switch_thread_cond_destroy(switch_thread_cond_t *cond) { return apr_thread_cond_destroy(cond); } /* file i/o stubs */ SWITCH_DECLARE(switch_status_t) switch_file_open(switch_file_t ** newf, const char *fname, int32_t flag, switch_fileperms_t perm, switch_memory_pool_t *pool) { return apr_file_open(newf, fname, flag, perm, pool); } SWITCH_DECLARE(switch_status_t) switch_file_seek(switch_file_t *thefile, switch_seek_where_t where, int64_t *offset) { apr_status_t rv; apr_off_t off = (apr_off_t) (*offset); rv = apr_file_seek(thefile, where, &off); *offset = (int64_t) off; return rv; } SWITCH_DECLARE(switch_status_t) switch_file_copy(const char *from_path, const char *to_path, switch_fileperms_t perms, switch_memory_pool_t *pool) { return apr_file_copy(from_path, to_path, perms, pool); } SWITCH_DECLARE(switch_status_t) switch_file_close(switch_file_t *thefile) { return apr_file_close(thefile); } SWITCH_DECLARE(switch_status_t) switch_file_trunc(switch_file_t *thefile, int64_t offset) { return apr_file_trunc(thefile, offset); } SWITCH_DECLARE(switch_status_t) switch_file_lock(switch_file_t *thefile, int type) { return apr_file_lock(thefile, type); } SWITCH_DECLARE(switch_status_t) switch_file_rename(const char *from_path, const char *to_path, switch_memory_pool_t *pool) { return apr_file_rename(from_path, to_path, pool); } SWITCH_DECLARE(switch_status_t) switch_file_remove(const char *path, switch_memory_pool_t *pool) { return apr_file_remove(path, pool); } SWITCH_DECLARE(switch_status_t) switch_file_read(switch_file_t *thefile, void *buf, switch_size_t *nbytes) { return apr_file_read(thefile, buf, nbytes); } SWITCH_DECLARE(switch_status_t) switch_file_write(switch_file_t *thefile, const void *buf, switch_size_t *nbytes) { return apr_file_write(thefile, buf, nbytes); } SWITCH_DECLARE(int) switch_file_printf(switch_file_t *thefile, const char *format, ...) { va_list ap; int ret; char *data; va_start(ap, format); if ((ret = switch_vasprintf(&data, format, ap)) != -1) { switch_size_t bytes = strlen(data); switch_file_write(thefile, data, &bytes); free(data); } va_end(ap); return ret; } SWITCH_DECLARE(switch_status_t) switch_file_mktemp(switch_file_t ** thefile, char *templ, int32_t flags, switch_memory_pool_t *pool) { return apr_file_mktemp(thefile, templ, flags, pool); } SWITCH_DECLARE(switch_size_t) switch_file_get_size(switch_file_t *thefile) { struct apr_finfo_t finfo; return apr_file_info_get(&finfo, APR_FINFO_SIZE, thefile) == SWITCH_STATUS_SUCCESS ? (switch_size_t) finfo.size : 0; } SWITCH_DECLARE(switch_status_t) switch_directory_exists(const char *dirname, switch_memory_pool_t *pool) { apr_dir_t *dir_handle; switch_memory_pool_t *our_pool = NULL; switch_status_t status; if (!pool) { switch_core_new_memory_pool(&our_pool); pool = our_pool; } if ((status = apr_dir_open(&dir_handle, dirname, pool)) == APR_SUCCESS) { apr_dir_close(dir_handle); } if (our_pool) { switch_core_destroy_memory_pool(&our_pool); } return status; } SWITCH_DECLARE(switch_status_t) switch_file_exists(const char *filename, switch_memory_pool_t *pool) { int32_t wanted = APR_FINFO_TYPE; switch_memory_pool_t *our_pool = NULL; switch_status_t status = SWITCH_STATUS_FALSE; apr_finfo_t info = { 0 }; if (zstr(filename)) { return status; } if (!pool) { switch_core_new_memory_pool(&our_pool); } apr_stat(&info, filename, wanted, pool ? pool : our_pool); if (info.filetype != APR_NOFILE) { status = SWITCH_STATUS_SUCCESS; } if (our_pool) { switch_core_destroy_memory_pool(&our_pool); } return status; } SWITCH_DECLARE(switch_status_t) switch_dir_make(const char *path, switch_fileperms_t perm, switch_memory_pool_t *pool) { return apr_dir_make(path, perm, pool); } SWITCH_DECLARE(switch_status_t) switch_dir_make_recursive(const char *path, switch_fileperms_t perm, switch_memory_pool_t *pool) { return apr_dir_make_recursive(path, perm, pool); } struct switch_dir { apr_dir_t *dir_handle; apr_finfo_t finfo; }; SWITCH_DECLARE(switch_status_t) switch_dir_open(switch_dir_t ** new_dir, const char *dirname, switch_memory_pool_t *pool) { switch_status_t status; switch_dir_t *dir = malloc(sizeof(*dir)); if (!dir) { *new_dir = NULL; return SWITCH_STATUS_FALSE; } memset(dir, 0, sizeof(*dir)); if ((status = apr_dir_open(&(dir->dir_handle), dirname, pool)) == APR_SUCCESS) { *new_dir = dir; } else { free(dir); *new_dir = NULL; } return status; } SWITCH_DECLARE(switch_status_t) switch_dir_close(switch_dir_t *thedir) { switch_status_t status = apr_dir_close(thedir->dir_handle); free(thedir); return status; } SWITCH_DECLARE(uint32_t) switch_dir_count(switch_dir_t *thedir) { const char *name; apr_int32_t finfo_flags = APR_FINFO_DIRENT | APR_FINFO_TYPE | APR_FINFO_NAME; uint32_t count = 0; apr_dir_rewind(thedir->dir_handle); while (apr_dir_read(&(thedir->finfo), finfo_flags, thedir->dir_handle) == SWITCH_STATUS_SUCCESS) { if (thedir->finfo.filetype != APR_REG && thedir->finfo.filetype != APR_LNK) { continue; } if (!(name = thedir->finfo.fname)) { name = thedir->finfo.name; } if (name) { count++; } } apr_dir_rewind(thedir->dir_handle); return count; } SWITCH_DECLARE(const char *) switch_dir_next_file(switch_dir_t *thedir, char *buf, switch_size_t len) { const char *fname = NULL; apr_int32_t finfo_flags = APR_FINFO_DIRENT | APR_FINFO_TYPE | APR_FINFO_NAME; const char *name; while (apr_dir_read(&(thedir->finfo), finfo_flags, thedir->dir_handle) == SWITCH_STATUS_SUCCESS) { if (thedir->finfo.filetype != APR_REG && thedir->finfo.filetype != APR_LNK) { continue; } if (!(name = thedir->finfo.fname)) { name = thedir->finfo.name; } if (name) { switch_copy_string(buf, name, len); fname = buf; break; } else { continue; } } return fname; } /* thread stubs */ #ifndef WIN32 struct apr_threadattr_t { apr_pool_t *pool; pthread_attr_t attr; int priority; }; #else /* this needs to be revisited when apr for windows supports thread priority settings */ /* search for WIN32 in this file */ struct apr_threadattr_t { apr_pool_t *pool; apr_int32_t detach; apr_size_t stacksize; int priority; }; #endif SWITCH_DECLARE(switch_status_t) switch_threadattr_create(switch_threadattr_t ** new_attr, switch_memory_pool_t *pool) { switch_status_t status; if ((status = apr_threadattr_create(new_attr, pool)) == SWITCH_STATUS_SUCCESS) { (*new_attr)->priority = SWITCH_PRI_LOW; } return status; } SWITCH_DECLARE(switch_status_t) switch_threadattr_detach_set(switch_threadattr_t *attr, int32_t on) { return apr_threadattr_detach_set(attr, on); } SWITCH_DECLARE(switch_status_t) switch_threadattr_stacksize_set(switch_threadattr_t *attr, switch_size_t stacksize) { return apr_threadattr_stacksize_set(attr, stacksize); } SWITCH_DECLARE(switch_status_t) switch_threadattr_priority_set(switch_threadattr_t *attr, switch_thread_priority_t priority) { attr->priority = priority; return SWITCH_STATUS_SUCCESS; } static char TT_KEY[] = "1"; SWITCH_DECLARE(switch_status_t) switch_thread_create(switch_thread_t ** new_thread, switch_threadattr_t *attr, switch_thread_start_t func, void *data, switch_memory_pool_t *cont) { switch_core_memory_pool_set_data(cont, "_in_thread", TT_KEY); return apr_thread_create(new_thread, attr, func, data, cont); } SWITCH_DECLARE(switch_interval_time_t) switch_interval_time_from_timeval(struct timeval *tvp) { return ((switch_interval_time_t)tvp->tv_sec * 1000000) + tvp->tv_usec / 1000; } /* socket stubs */ SWITCH_DECLARE(switch_status_t) switch_os_sock_get(switch_os_socket_t *thesock, switch_socket_t *sock) { return apr_os_sock_get(thesock, sock); } SWITCH_DECLARE(switch_status_t) switch_os_sock_put(switch_socket_t **sock, switch_os_socket_t *thesock, switch_memory_pool_t *pool) { return apr_os_sock_put(sock, thesock, pool); } SWITCH_DECLARE(switch_status_t) switch_socket_addr_get(switch_sockaddr_t ** sa, switch_bool_t remote, switch_socket_t *sock) { return apr_socket_addr_get(sa, (apr_interface_e) remote, sock); } SWITCH_DECLARE(switch_status_t) switch_socket_create(switch_socket_t ** new_sock, int family, int type, int protocol, switch_memory_pool_t *pool) { return apr_socket_create(new_sock, family, type, protocol, pool); } SWITCH_DECLARE(switch_status_t) switch_socket_shutdown(switch_socket_t *sock, switch_shutdown_how_e how) { return apr_socket_shutdown(sock, (apr_shutdown_how_e) how); } SWITCH_DECLARE(switch_status_t) switch_socket_close(switch_socket_t *sock) { return apr_socket_close(sock); } SWITCH_DECLARE(switch_status_t) switch_socket_bind(switch_socket_t *sock, switch_sockaddr_t *sa) { return apr_socket_bind(sock, sa); } SWITCH_DECLARE(switch_status_t) switch_socket_listen(switch_socket_t *sock, int32_t backlog) { return apr_socket_listen(sock, backlog); } SWITCH_DECLARE(switch_status_t) switch_socket_accept(switch_socket_t ** new_sock, switch_socket_t *sock, switch_memory_pool_t *pool) { return apr_socket_accept(new_sock, sock, pool); } SWITCH_DECLARE(switch_status_t) switch_socket_connect(switch_socket_t *sock, switch_sockaddr_t *sa) { return apr_socket_connect(sock, sa); } SWITCH_DECLARE(switch_status_t) switch_socket_send(switch_socket_t *sock, const char *buf, switch_size_t *len) { int status = SWITCH_STATUS_SUCCESS; switch_size_t req = *len, wrote = 0, need = *len; int to_count = 0; while ((wrote < req && status == SWITCH_STATUS_SUCCESS) || (need == 0 && status == SWITCH_STATUS_BREAK) || status == 730035 || status == 35) { need = req - wrote; status = apr_socket_send(sock, buf + wrote, &need); if (status == SWITCH_STATUS_BREAK || status == 730035 || status == 35) { if (++to_count > 60000) { status = SWITCH_STATUS_FALSE; break; } switch_yield(10000); } else { to_count = 0; } wrote += need; } *len = wrote; return (switch_status_t)status; } SWITCH_DECLARE(switch_status_t) switch_socket_send_nonblock(switch_socket_t *sock, const char *buf, switch_size_t *len) { if (!sock || !buf || !len) { return SWITCH_STATUS_GENERR; } return apr_socket_send(sock, buf, len); } SWITCH_DECLARE(switch_status_t) switch_socket_sendto(switch_socket_t *sock, switch_sockaddr_t *where, int32_t flags, const char *buf, switch_size_t *len) { if (!where || !buf || !len || !*len) { return SWITCH_STATUS_GENERR; } return apr_socket_sendto(sock, where, flags, buf, len); } SWITCH_DECLARE(switch_status_t) switch_socket_recv(switch_socket_t *sock, char *buf, switch_size_t *len) { int r; r = apr_socket_recv(sock, buf, len); if (r == 35 || r == 730035) { r = SWITCH_STATUS_BREAK; } return (switch_status_t)r; } SWITCH_DECLARE(switch_status_t) switch_sockaddr_create(switch_sockaddr_t **sa, switch_memory_pool_t *pool) { switch_sockaddr_t *new_sa; unsigned short family = APR_INET; new_sa = apr_pcalloc(pool, sizeof(apr_sockaddr_t)); switch_assert(new_sa); new_sa->pool = pool; memset(new_sa, 0, sizeof(*new_sa)); new_sa->family = family; new_sa->sa.sin.sin_family = family; new_sa->salen = sizeof(struct sockaddr_in); new_sa->addr_str_len = 16; new_sa->ipaddr_ptr = &(new_sa->sa.sin.sin_addr); new_sa->ipaddr_len = sizeof(struct in_addr); *sa = new_sa; return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_sockaddr_info_get(switch_sockaddr_t ** sa, const char *hostname, int32_t family, switch_port_t port, int32_t flags, switch_memory_pool_t *pool) { return apr_sockaddr_info_get(sa, hostname, family, port, flags, pool); } SWITCH_DECLARE(switch_status_t) switch_socket_opt_set(switch_socket_t *sock, int32_t opt, int32_t on) { if (opt == SWITCH_SO_TCP_KEEPIDLE) { int r = -10; #if defined(TCP_KEEPIDLE) r = setsockopt(jsock->client_socket, SOL_TCP, TCP_KEEPIDLE, (void *)&on, sizeof(on)); #endif if (r == -10) { return SWITCH_STATUS_NOTIMPL; } return r ? SWITCH_STATUS_FALSE : SWITCH_STATUS_SUCCESS; } if (opt == SWITCH_SO_TCP_KEEPINTVL) { int r = -10; #if defined(TCP_KEEPINTVL) r = setsockopt(jsock->client_socket, SOL_TCP, TCP_KEEPINTVL, (void *)&on, sizeof(on)); #endif if (r == -10) { return SWITCH_STATUS_NOTIMPL; } return r ? SWITCH_STATUS_FALSE : SWITCH_STATUS_SUCCESS; } return apr_socket_opt_set(sock, opt, on); } SWITCH_DECLARE(switch_status_t) switch_socket_timeout_get(switch_socket_t *sock, switch_interval_time_t *t) { apr_interval_time_t at = 0; switch_status_t status = apr_socket_timeout_get(sock, &at); *t = at; return status; } SWITCH_DECLARE(switch_status_t) switch_socket_timeout_set(switch_socket_t *sock, switch_interval_time_t t) { return apr_socket_timeout_set(sock, t); } SWITCH_DECLARE(switch_status_t) switch_sockaddr_ip_get(char **addr, switch_sockaddr_t *sa) { return apr_sockaddr_ip_get(addr, sa); } SWITCH_DECLARE(int) switch_sockaddr_equal(const switch_sockaddr_t *sa1, const switch_sockaddr_t *sa2) { return apr_sockaddr_equal(sa1, sa2); } SWITCH_DECLARE(switch_status_t) switch_mcast_join(switch_socket_t *sock, switch_sockaddr_t *join, switch_sockaddr_t *iface, switch_sockaddr_t *source) { return apr_mcast_join(sock, join, iface, source); } SWITCH_DECLARE(switch_status_t) switch_mcast_hops(switch_socket_t *sock, uint8_t ttl) { return apr_mcast_hops(sock, ttl); } SWITCH_DECLARE(switch_status_t) switch_mcast_loopback(switch_socket_t *sock, uint8_t opt) { return apr_mcast_loopback(sock, opt); } SWITCH_DECLARE(switch_status_t) switch_mcast_interface(switch_socket_t *sock, switch_sockaddr_t *iface) { return apr_mcast_interface(sock, iface); } /* socket functions */ SWITCH_DECLARE(const char *) switch_get_addr(char *buf, switch_size_t len, switch_sockaddr_t *in) { if (!in) { return SWITCH_BLANK_STRING; } memset(buf, 0, len); if (in->family == AF_INET) { get_addr(buf, len, (struct sockaddr *) &in->sa, in->salen); return buf; } get_addr6(buf, len, (struct sockaddr_in6 *) &in->sa, in->salen); return buf; } SWITCH_DECLARE(int) switch_socket_fd_get(switch_socket_t *sock) { return apr_socket_fd_get(sock); } SWITCH_DECLARE(uint16_t) switch_sockaddr_get_port(switch_sockaddr_t *sa) { return sa->port; } SWITCH_DECLARE(int32_t) switch_sockaddr_get_family(switch_sockaddr_t *sa) { return sa->family; } SWITCH_DECLARE(switch_status_t) switch_getnameinfo(char **hostname, switch_sockaddr_t *sa, int32_t flags) { return apr_getnameinfo(hostname, sa, flags); } SWITCH_DECLARE(switch_status_t) switch_socket_atmark(switch_socket_t *sock, int *atmark) { return apr_socket_atmark(sock, atmark); } SWITCH_DECLARE(switch_status_t) switch_socket_recvfrom(switch_sockaddr_t *from, switch_socket_t *sock, int32_t flags, char *buf, size_t *len) { int r = SWITCH_STATUS_GENERR; if (from && sock && (r = apr_socket_recvfrom(from, sock, flags, buf, len)) == APR_SUCCESS) { from->port = ntohs(from->sa.sin.sin_port); /* from->ipaddr_ptr = &(from->sa.sin.sin_addr); * from->ipaddr_ptr = inet_ntoa(from->sa.sin.sin_addr); */ } if (r == 35 || r == 730035) { r = SWITCH_STATUS_BREAK; } return (switch_status_t)r; } /* poll stubs */ SWITCH_DECLARE(switch_status_t) switch_pollset_create(switch_pollset_t ** pollset, uint32_t size, switch_memory_pool_t *pool, uint32_t flags) { return apr_pollset_create(pollset, size, pool, flags); } SWITCH_DECLARE(switch_status_t) switch_pollset_add(switch_pollset_t *pollset, const switch_pollfd_t *descriptor) { if (!pollset || !descriptor) { return SWITCH_STATUS_FALSE; } return apr_pollset_add((apr_pollset_t *) pollset, (const apr_pollfd_t *) descriptor); } SWITCH_DECLARE(switch_status_t) switch_pollset_remove(switch_pollset_t *pollset, const switch_pollfd_t *descriptor) { if (!pollset || !descriptor) { return SWITCH_STATUS_FALSE; } return apr_pollset_remove((apr_pollset_t *) pollset, (const apr_pollfd_t *) descriptor); } SWITCH_DECLARE(switch_status_t) switch_socket_create_pollfd(switch_pollfd_t **pollfd, switch_socket_t *sock, int16_t flags, void *client_data, switch_memory_pool_t *pool) { if (!pollfd || !sock) { return SWITCH_STATUS_FALSE; } if ((*pollfd = (switch_pollfd_t*)apr_palloc(pool, sizeof(switch_pollfd_t))) == 0) { return SWITCH_STATUS_MEMERR; } memset(*pollfd, 0, sizeof(switch_pollfd_t)); (*pollfd)->desc_type = (switch_pollset_type_t) APR_POLL_SOCKET; (*pollfd)->reqevents = flags; (*pollfd)->desc.s = sock; (*pollfd)->client_data = client_data; return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_pollset_poll(switch_pollset_t *pollset, switch_interval_time_t timeout, int32_t *num, const switch_pollfd_t **descriptors) { apr_status_t st = SWITCH_STATUS_FALSE; if (pollset) { st = apr_pollset_poll((apr_pollset_t *) pollset, timeout, num, (const apr_pollfd_t **) descriptors); if (st == APR_TIMEUP) { st = SWITCH_STATUS_TIMEOUT; } } return st; } SWITCH_DECLARE(switch_status_t) switch_poll(switch_pollfd_t *aprset, int32_t numsock, int32_t *nsds, switch_interval_time_t timeout) { apr_status_t st = SWITCH_STATUS_FALSE; if (aprset) { st = apr_poll((apr_pollfd_t *) aprset, numsock, nsds, timeout); if (numsock == 1 && ((aprset[0].rtnevents & APR_POLLERR) || (aprset[0].rtnevents & APR_POLLHUP) || (aprset[0].rtnevents & APR_POLLNVAL))) { st = SWITCH_STATUS_GENERR; } else if (st == APR_TIMEUP) { st = SWITCH_STATUS_TIMEOUT; } } return st; } SWITCH_DECLARE(switch_status_t) switch_socket_create_pollset(switch_pollfd_t ** poll, switch_socket_t *sock, int16_t flags, switch_memory_pool_t *pool) { switch_pollset_t *pollset; if (switch_pollset_create(&pollset, 1, pool, 0) != SWITCH_STATUS_SUCCESS) { return SWITCH_STATUS_GENERR; } if (switch_socket_create_pollfd(poll, sock, flags, sock, pool) != SWITCH_STATUS_SUCCESS) { return SWITCH_STATUS_GENERR; } if (switch_pollset_add(pollset, *poll) != SWITCH_STATUS_SUCCESS) { return SWITCH_STATUS_GENERR; } return SWITCH_STATUS_SUCCESS; } /* apr-util stubs */ /* UUID Handling (apr-util) */ SWITCH_DECLARE(void) switch_uuid_format(char *buffer, const switch_uuid_t *uuid) { #ifndef WIN32 apr_uuid_format(buffer, (const apr_uuid_t *) uuid); #else RPC_CSTR buf; UuidToString((const UUID *) uuid, &buf); strcpy(buffer, (const char *) buf); RpcStringFree(&buf); #endif } SWITCH_DECLARE(void) switch_uuid_get(switch_uuid_t *uuid) { switch_mutex_lock(runtime.uuid_mutex); #ifndef WIN32 apr_uuid_get((apr_uuid_t *) uuid); #else UuidCreate((UUID *) uuid); #endif switch_mutex_unlock(runtime.uuid_mutex); } SWITCH_DECLARE(switch_status_t) switch_uuid_parse(switch_uuid_t *uuid, const char *uuid_str) { #ifndef WIN32 return apr_uuid_parse((apr_uuid_t *) uuid, uuid_str); #else return UuidFromString((RPC_CSTR) uuid_str, (UUID *) uuid); #endif } SWITCH_DECLARE(switch_status_t) switch_md5(unsigned char digest[SWITCH_MD5_DIGESTSIZE], const void *input, switch_size_t inputLen) { #if (defined(HAVE_LIBMD5) || defined(HAVE_LIBMD) || defined(HAVE_MD5INIT)) MD5_CTX md5_context; MD5Init(&md5_context); MD5Update(&md5_context, input, inputLen); MD5Final(digest, &md5_context); return SWITCH_STATUS_SUCCESS; #elif defined(HAVE_LIBCRYPTO) MD5_CTX md5_context; MD5_Init(&md5_context); MD5_Update(&md5_context, input, inputLen); MD5_Final(digest, &md5_context); return SWITCH_STATUS_SUCCESS; #else return apr_md5(digest, input, inputLen); #endif } SWITCH_DECLARE(switch_status_t) switch_md5_string(char digest_str[SWITCH_MD5_DIGEST_STRING_SIZE], const void *input, switch_size_t inputLen) { unsigned char digest[SWITCH_MD5_DIGESTSIZE]; switch_status_t status = switch_md5(digest, input, inputLen); short i, x; uint8_t b; digest_str[SWITCH_MD5_DIGEST_STRING_SIZE - 1] = '\0'; for (x = i = 0; x < SWITCH_MD5_DIGESTSIZE; x++) { b = (digest[x] >> 4) & 15; digest_str[i++] = b + (b > 9 ? 'a' - 10 : '0'); b = digest[x] & 15; digest_str[i++] = b + (b > 9 ? 'a' - 10 : '0'); } digest_str[i] = '\0'; return status; } /* FIFO queues (apr-util) */ SWITCH_DECLARE(switch_status_t) switch_queue_create(switch_queue_t ** queue, unsigned int queue_capacity, switch_memory_pool_t *pool) { return apr_queue_create(queue, queue_capacity, pool); } SWITCH_DECLARE(unsigned int) switch_queue_size(switch_queue_t *queue) { return apr_queue_size(queue); } SWITCH_DECLARE(switch_status_t) switch_queue_pop(switch_queue_t *queue, void **data) { return apr_queue_pop(queue, data); } SWITCH_DECLARE(switch_status_t) switch_queue_pop_timeout(switch_queue_t *queue, void **data, switch_interval_time_t timeout) { return apr_queue_pop_timeout(queue, data, timeout); } SWITCH_DECLARE(switch_status_t) switch_queue_push(switch_queue_t *queue, void *data) { apr_status_t s; do { s = apr_queue_push(queue, data); } while (s == APR_EINTR); return s; } SWITCH_DECLARE(switch_status_t) switch_queue_trypop(switch_queue_t *queue, void **data) { return apr_queue_trypop(queue, data); } SWITCH_DECLARE(switch_status_t) switch_queue_interrupt_all(switch_queue_t *queue) { return apr_queue_interrupt_all(queue); } SWITCH_DECLARE(switch_status_t) switch_queue_term(switch_queue_t *queue) { return apr_queue_term(queue); } SWITCH_DECLARE(switch_status_t) switch_queue_trypush(switch_queue_t *queue, void *data) { apr_status_t s; do { s = apr_queue_trypush(queue, data); } while (s == APR_EINTR); return s; } SWITCH_DECLARE(int) switch_vasprintf(char **ret, const char *fmt, va_list ap) { #ifdef HAVE_VASPRINTF return vasprintf(ret, fmt, ap); #else char *buf; int len; size_t buflen; va_list ap2; char *tmp = NULL; #ifdef _MSC_VER #if _MSC_VER >= 1500 /* hack for incorrect assumption in msvc header files for code analysis */ __analysis_assume(tmp); #endif ap2 = ap; #else va_copy(ap2, ap); #endif len = vsnprintf(tmp, 0, fmt, ap2); if (len > 0 && (buf = malloc((buflen = (size_t) (len + 1)))) != NULL) { len = vsnprintf(buf, buflen, fmt, ap); *ret = buf; } else { *ret = NULL; len = -1; } va_end(ap2); return len; #endif } SWITCH_DECLARE(switch_status_t) switch_match_glob(const char *pattern, switch_array_header_t ** result, switch_memory_pool_t *pool) { return apr_match_glob(pattern, (apr_array_header_t **) result, pool); } /** * Create an anonymous pipe. * @param in The file descriptor to use as input to the pipe. * @param out The file descriptor to use as output from the pipe. * @param pool The pool to operate on. */ SWITCH_DECLARE(switch_status_t) switch_file_pipe_create(switch_file_t ** in, switch_file_t ** out, switch_memory_pool_t *pool) { return apr_file_pipe_create((apr_file_t **) in, (apr_file_t **) out, pool); } /** * Get the timeout value for a pipe or manipulate the blocking state. * @param thepipe The pipe we are getting a timeout for. * @param timeout The current timeout value in microseconds. */ SWITCH_DECLARE(switch_status_t) switch_file_pipe_timeout_get(switch_file_t *thepipe, switch_interval_time_t *timeout) { return apr_file_pipe_timeout_get((apr_file_t *) thepipe, (apr_interval_time_t *) timeout); } /** * Set the timeout value for a pipe or manipulate the blocking state. * @param thepipe The pipe we are setting a timeout on. * @param timeout The timeout value in microseconds. Values < 0 mean wait * forever, 0 means do not wait at all. */ SWITCH_DECLARE(switch_status_t) switch_file_pipe_timeout_set(switch_file_t *thepipe, switch_interval_time_t timeout) { return apr_file_pipe_timeout_set((apr_file_t *) thepipe, (apr_interval_time_t) timeout); } /** * stop the current thread * @param thd The thread to stop * @param retval The return value to pass back to any thread that cares */ SWITCH_DECLARE(switch_status_t) switch_thread_exit(switch_thread_t *thd, switch_status_t retval) { return apr_thread_exit((apr_thread_t *) thd, retval); } /** * block until the desired thread stops executing. * @param retval The return value from the dead thread. * @param thd The thread to join */ SWITCH_DECLARE(switch_status_t) switch_thread_join(switch_status_t *retval, switch_thread_t *thd) { if ( !thd ) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "ERROR: Attempting to join thread that does not exist\n"); return SWITCH_STATUS_FALSE; } return apr_thread_join((apr_status_t *) retval, (apr_thread_t *) thd); } SWITCH_DECLARE(switch_status_t) switch_atomic_init(switch_memory_pool_t *pool) { return apr_atomic_init((apr_pool_t *) pool); } SWITCH_DECLARE(uint32_t) switch_atomic_read(volatile switch_atomic_t *mem) { #ifdef apr_atomic_t return apr_atomic_read((apr_atomic_t *)mem); #else return apr_atomic_read32((apr_uint32_t *)mem); #endif } SWITCH_DECLARE(void) switch_atomic_set(volatile switch_atomic_t *mem, uint32_t val) { #ifdef apr_atomic_t apr_atomic_set((apr_atomic_t *)mem, val); #else apr_atomic_set32((apr_uint32_t *)mem, val); #endif } SWITCH_DECLARE(void) switch_atomic_add(volatile switch_atomic_t *mem, uint32_t val) { #ifdef apr_atomic_t apr_atomic_add((apr_atomic_t *)mem, val); #else apr_atomic_add32((apr_uint32_t *)mem, val); #endif } SWITCH_DECLARE(void) switch_atomic_inc(volatile switch_atomic_t *mem) { #ifdef apr_atomic_t apr_atomic_inc((apr_atomic_t *)mem); #else apr_atomic_inc32((apr_uint32_t *)mem); #endif } SWITCH_DECLARE(int) switch_atomic_dec(volatile switch_atomic_t *mem) { #ifdef apr_atomic_t return apr_atomic_dec((apr_atomic_t *)mem); #else return apr_atomic_dec32((apr_uint32_t *)mem); #endif } SWITCH_DECLARE(char *) switch_strerror(switch_status_t statcode, char *buf, switch_size_t bufsize) { return apr_strerror(statcode, buf, bufsize); } /* For Emacs: * Local Variables: * mode:c * indent-tabs-mode:t * tab-width:4 * c-basic-offset:4 * End: * For VIM: * vim:set softtabstop=4 shiftwidth=4 tabstop=4 noet: */