/* * Copyright (C) 2003-2011 The Music Player Daemon Project * http://www.musicpd.org * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "output_api.h" #include "mixer_list.h" #include "raop_output_plugin.h" #include "../utils.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #undef G_LOG_DOMAIN #define G_LOG_DOMAIN "raop" static struct raop_session_data *raop_session = NULL; /** * The quark used for GError.domain. */ static inline GQuark raop_output_quark(void) { return g_quark_from_static_string("raop_output"); } static struct raop_data * new_raop_data(void) { struct raop_data *ret = g_new(struct raop_data, 1); int i; pthread_mutex_init(&ret->control_mutex, NULL); ret->next = NULL; ret->is_master = 0; ret->started = 0; ret->paused = 0; if (raop_session == NULL) { raop_session = (struct raop_session_data *) malloc(sizeof(struct raop_session_data)); raop_session->raop_list = NULL; raop_session->ntp.port = 6002; raop_session->ntp.fd = -1; raop_session->ctrl.port = 6001; raop_session->ctrl.fd = -1; raop_session->play_state.playing = false; raop_session->play_state.seq_num = (short) g_random_int(); raop_session->play_state.rtptime = g_random_int(); raop_session->play_state.sync_src = g_random_int(); raop_session->play_state.last_send.tv_sec = 0; raop_session->play_state.last_send.tv_usec = 0; if (!RAND_bytes(raop_session->encrypt.iv, sizeof(raop_session->encrypt.iv)) || !RAND_bytes(raop_session->encrypt.key, sizeof(raop_session->encrypt.key))) { g_warning("%s:RAND_bytes error code=%ld\n",__func__,ERR_get_error()); return NULL; } memcpy(raop_session->encrypt.nv, raop_session->encrypt.iv, sizeof(raop_session->encrypt.nv)); for (i = 0; i < 16; i++) { printf("0x%x ", raop_session->encrypt.key[i]); } printf("\n"); AES_set_encrypt_key(raop_session->encrypt.key, 128, &raop_session->encrypt.ctx); raop_session->data_fd = -1; bzero(raop_session->buffer, RAOP_BUFFER_SIZE); raop_session->bufferSize = 0; pthread_mutex_init(&raop_session->data_mutex, NULL); pthread_mutex_init(&raop_session->list_mutex, NULL); } return ret; } /* * read one line from the file descriptor * timeout: msec unit, -1 for infinite * if CR comes then following LF is expected * returned string in line is always null terminated, maxlen-1 is maximum string length */ static int read_line(int fd, char *line, int maxlen, int timeout, int no_poll) { int i, rval; int count = 0; struct pollfd pfds; char ch; *line = 0; pfds.events = POLLIN; pfds.fd = fd; for (i = 0;i < maxlen; i++) { if (no_poll || poll(&pfds, 1, timeout)) rval=read(fd,&ch,1); else return 0; if (rval == -1) { if (errno == EAGAIN) return 0; g_warning("%s:read error: %s\n", __func__, strerror(errno)); return -1; } if (rval == 0) { g_debug("%s:disconnected on the other end\n", __func__); return -1; } if(ch == '\n') { *line = 0; return count; } if (ch == '\r') continue; *line++ = ch; count++; if (count >= maxlen - 1) break; } *line = 0; return count; } /* * Free all memory associated with key_data */ static void free_kd(struct key_data *kd) { struct key_data *iter = kd; while (iter) { free(iter->key); if(iter->data) free(iter->data); iter = iter->next; free(kd); kd = iter; } } /* * key_data type data look up */ static char * kd_lookup(struct key_data *kd, const char *key) { while (kd) { g_debug("checking key %s %s\n", kd->key, key); if (!strcmp((char*)kd->key, key)) { g_debug("found %s\n", kd->data); return (char*) kd->data; } kd = kd->next; } return NULL; } /* * remove one character from a string * return the number of deleted characters */ static int remove_char_from_string(char *str, char rc) { int i = 0, j = 0, len; int num = 0; len = strlen(str); while (i < len) { if (str[i] == rc) { for (j = i; j < len; j++) str[j] = str[j + 1]; len--; num++; } else { i++; } } return num; } #define SLEEP_MSEC(val) usleep(val*1000) /* bind an opened socket to specified hostname and port. * if hostname=NULL, use INADDR_ANY. * if *port=0, use dynamically assigned port */ static int bind_host(int sd, char *hostname, unsigned long ulAddr, unsigned short *port) { struct sockaddr_in my_addr; socklen_t nlen = sizeof(struct sockaddr); struct hostent *h; memset(&my_addr, 0, sizeof(my_addr)); /* use specified hostname */ if (hostname) { /* get server IP address (no check if input is IP address or DNS name) */ h = gethostbyname(hostname); if (h == NULL) { if (strstr(hostname, "255.255.255.255") == hostname) { my_addr.sin_addr.s_addr=-1; } else { if ((my_addr.sin_addr.s_addr = inet_addr(hostname)) == 0xFFFFFFFF) { g_warning("gethostbyname: '%s' \n", hostname); return -1; } } my_addr.sin_family = AF_INET; } else { my_addr.sin_family = h->h_addrtype; memcpy((char *) &my_addr.sin_addr.s_addr, h->h_addr_list[0], h->h_length); } } else { // if hostname=NULL, use INADDR_ANY if (ulAddr) my_addr.sin_addr.s_addr = ulAddr; else my_addr.sin_addr.s_addr = htonl(INADDR_ANY); my_addr.sin_family = AF_INET; } /* bind a specified port */ my_addr.sin_port = htons(*port); if (bind(sd, (struct sockaddr *) &my_addr, sizeof(my_addr)) < 0) { g_warning("bind error: %s\n", strerror(errno)); return -1; } if (*port == 0) { getsockname(sd, (struct sockaddr *) &my_addr, &nlen); *port = ntohs(my_addr.sin_port); } return 0; } /* * open tcp port */ static int open_tcp_socket(char *hostname, unsigned short *port) { int sd; /* socket creation */ sd = socket(AF_INET, SOCK_STREAM, 0); if (sd < 0) { g_warning("cannot create tcp socket\n"); return -1; } if (bind_host(sd, hostname,0, port)) { close(sd); return -1; } return sd; } /* * open udp port */ static int open_udp_socket(char *hostname, unsigned short *port) { int sd; int size = 30000; /* socket creation */ sd = socket(PF_INET, SOCK_DGRAM, 0); if (sd < 0) { g_warning("cannot create udp socket\n"); return -1; } if (setsockopt(sd, SOL_SOCKET, SO_SNDBUF, (void *) &size, sizeof(size)) < 0) { g_warning("Could not set udp send buffer to %d\n", size); return -1; } if (bind_host(sd, hostname,0, port)) { close(sd); return -1; } return sd; } /* * create tcp connection * as long as the socket is not non-blocking, this can block the process * nsport is network byte order */ static bool get_tcp_connect(int sd, struct sockaddr_in dest_addr) { if (connect(sd, (struct sockaddr *)&dest_addr, sizeof(struct sockaddr))){ SLEEP_MSEC(100L); // try one more time if (connect(sd, (struct sockaddr *)&dest_addr, sizeof(struct sockaddr))) { g_warning("error:get_tcp_nconnect addr=%s, port=%d\n", inet_ntoa(dest_addr.sin_addr), ntohs(dest_addr.sin_port)); return false; } } return true; } static bool get_sockaddr_by_host(const char *host, short destport, struct sockaddr_in *addr) { struct hostent *h; h = gethostbyname(host); if (h) { addr->sin_family = h->h_addrtype; memcpy((char *) &addr->sin_addr.s_addr, h->h_addr_list[0], h->h_length); } else { addr->sin_family = AF_INET; if ((addr->sin_addr.s_addr=inet_addr(host))==0xFFFFFFFF) { g_warning("gethostbyname: '%s' \n", host); return false; } } addr->sin_port = htons(destport); return true; } static bool get_tcp_connect_by_host(int sd, const char *host, short destport) { struct sockaddr_in addr; get_sockaddr_by_host(host, destport, &addr); return get_tcp_connect(sd, addr); } /* * Store time in the NTP format in the buffer */ static void fill_time_buffer_with_time(unsigned char *buffer, struct timeval *tout) { unsigned long secs_to_baseline = 964697997; int iter; double fraction; unsigned long long_fraction; unsigned long secs; fraction = ((double) tout->tv_usec) / 1000000.0; long_fraction = (unsigned long) (fraction * 256.0 * 256.0 * 256.0 * 256.0); secs = secs_to_baseline + tout->tv_sec; for (iter = 0; iter < 4; iter++) { buffer[iter] = (secs >> ((3 - iter) * 8)) & 0xff; } for (iter = 0; iter < 4; iter++) { buffer[4 + iter] = (long_fraction >> ((3 - iter) * 8)) & 0xff; } } /* * Calculate the current NTP time, store it in the buffer. */ static void fill_time_buffer(unsigned char *buffer) { struct timeval current_time; gettimeofday(¤t_time,NULL); fill_time_buffer_with_time(buffer, ¤t_time); } /* * Calculate the current NTP time, store it in the buffer. */ static void fill_int(unsigned char *buffer, unsigned int rtp_time) { int iter; for (iter = 0; iter < 4; iter++) { buffer[iter] = (rtp_time >> ((3 - iter) * 8)) & 0xff; } } /* * Recv the NTP datagram from the AirTunes, send back an NTP response. */ static bool send_timing_response(int fd) { unsigned char buf[32]; struct sockaddr addr; int iter; unsigned int addr_len = sizeof(addr); int num_bytes = recvfrom(fd, buf, sizeof(buf), 0, &addr, &addr_len); if (num_bytes == 0) { return false; } fill_time_buffer(buf + 16); // set to response buf[1] = 0xd3; // copy request for (iter = 0; iter < 8; iter++) { buf[8 + iter] = buf[24 + iter]; } fill_time_buffer(buf + 24); num_bytes = sendto(fd, buf, num_bytes, 0, &addr, addr_len); return num_bytes == sizeof(buf); } static bool get_time_for_rtp(struct play_state *state, struct timeval *tout) { unsigned long rtp_diff = state->rtptime - state->start_rtptime; unsigned long add_secs = rtp_diff / 44100; unsigned long add_usecs = (((rtp_diff % 44100) * 10000) / 441) % 1000000; tout->tv_sec = state->start_time.tv_sec + add_secs; tout->tv_usec = state->start_time.tv_usec + add_usecs; if (tout->tv_usec >= 1000000) { tout->tv_sec++; tout->tv_usec = tout->tv_usec % 1000000; } return true; } /* * Send a control command */ bool send_control_command(struct control_data *ctrl, struct raop_data *rd, struct play_state *state) { unsigned char buf[20]; int diff; int num_bytes; struct timeval ctrl_time; diff = 88200; if (rd->started) { buf[0] = 0x80; diff += NUMSAMPLES; } else { buf[0] = 0x90; state->playing = true; state->start_rtptime = state->rtptime; } buf[1] = 0xd4; buf[2] = 0x00; buf[3] = 0x07; fill_int(buf + 4, state->rtptime - diff); get_time_for_rtp(state, &ctrl_time); fill_time_buffer_with_time(buf + 8, &ctrl_time); fill_int(buf + 16, state->rtptime); num_bytes = sendto(ctrl->fd, buf, sizeof(buf), 0, (struct sockaddr *) &rd->ctrl_addr, sizeof(rd->ctrl_addr)); return true; } /* * check to see if there are any timing requests, and respond if there are any */ static bool check_timing(struct timeval *tout) { fd_set rdfds; int fdmax = 0; FD_ZERO(&rdfds); FD_SET(raop_session->ntp.fd, &rdfds); fdmax = raop_session->ntp.fd; select(fdmax + 1, &rdfds,NULL, NULL, tout); if (FD_ISSET(raop_session->ntp.fd, &rdfds)) { if (!send_timing_response(raop_session->ntp.fd)) { g_debug("unable to send timing response\n"); return false; } } return true; } /* * send RTSP request, and get response if it's needed * if this gets a success, *kd is allocated or reallocated (if *kd is not NULL) */ static bool exec_request(struct rtspcl_data *rtspcld, const char *cmd, const char *content_type, char *content, int get_response, struct key_data *hds, struct key_data **kd) { char line[1024]; char req[1024]; char reql[128]; const char delimiters[] = " "; char *token, *dp; int i,dsize = 0,rval; struct key_data *hd_iter, *cur_kd = *kd; unsigned int j; int timeout = 5000; // msec unit fd_set rdfds; int fdmax = 0; struct timeval tout = {.tv_sec=10, .tv_usec=0}; if (!rtspcld) return false; sprintf(req, "%s %s RTSP/1.0\r\nCSeq: %d\r\n", cmd, rtspcld->url, ++rtspcld->cseq ); if ( rtspcld->session != NULL ) { sprintf(reql,"Session: %s\r\n", rtspcld->session ); strncat(req,reql,sizeof(req)); } hd_iter = hds; while (hd_iter) { sprintf(reql, "%s: %s\r\n", hd_iter->key, hd_iter->data); strncat(req, reql, sizeof(req)); hd_iter = hd_iter->next; } if (content_type && content) { sprintf(reql, "Content-Type: %s\r\nContent-Length: %d\r\n", content_type, (int) strlen(content)); strncat(req,reql,sizeof(req)); } sprintf(reql, "User-Agent: %s\r\n", rtspcld->useragent); strncat(req, reql, sizeof(req)); hd_iter = rtspcld->exthds; while (hd_iter) { sprintf(reql, "%s: %s\r\n", hd_iter->key, hd_iter->data); strncat(req, reql, sizeof(req)); hd_iter = hd_iter->next; } strncat(req, "\r\n", sizeof(req)); if (content_type && content) strncat(req, content, sizeof(req)); rval = write(rtspcld->fd, req, strlen(req)); g_debug("sent %s", req); if (!get_response) return true; while (true) { FD_ZERO(&rdfds); FD_SET(rtspcld->fd, &rdfds); FD_SET(raop_session->ntp.fd, &rdfds); fdmax = raop_session->ntp.fd > rtspcld->fd ? raop_session->ntp.fd : rtspcld->fd;; select(fdmax + 1, &rdfds, NULL, NULL, &tout); if (FD_ISSET(rtspcld->fd, &rdfds)) { break; } if (FD_ISSET(raop_session->ntp.fd, &rdfds)) { send_timing_response(raop_session->ntp.fd); } } if (read_line(rtspcld->fd, line, sizeof(line), timeout, 0) <= 0) { g_warning("%s: request failed\n",__func__); return false; } g_debug("received %s", line); token = strtok(line, delimiters); token = strtok(NULL, delimiters); if (token == NULL || strcmp(token,"200")) { g_warning("%s: request failed, error %s\n", __func__, token); return false; } i = 0; while (read_line(rtspcld->fd, line, sizeof(line), timeout, 0) > 0) { struct key_data *new_kd = NULL; g_debug("%s -\n",line); timeout = 1000; // once it started, it shouldn't take a long time if (i && line[0] == ' ') { for (j = 0; j < strlen(line); j++) if (line[j] != ' ') break; dsize += strlen(line + j); if ((new_kd->data = realloc(new_kd->data, dsize))) return false; strcat((char*)new_kd->data, line + j); continue; } dp = strstr(line, ":"); if (!dp) { g_warning("%s: Request failed, bad header\n", __func__); free_kd(*kd); *kd = NULL; return false; } *dp = 0; new_kd = malloc(sizeof(struct key_data)); new_kd->key = malloc(strlen(line) + 1); strcpy((char *) new_kd->key, line); dsize = strlen(dp + 1) + 1; new_kd->data = malloc(dsize); strcpy((char*)new_kd->data, dp + 1); new_kd->next = NULL; if (cur_kd == NULL) { cur_kd = *kd = new_kd; } else { cur_kd->next = new_kd; cur_kd = new_kd; } i++; } return true; } static bool rtspcl_set_parameter(struct rtspcl_data *rtspcld, char *parameter) { return exec_request(rtspcld, "SET_PARAMETER", "text/parameters", parameter, 1, NULL, &rtspcld->kd); } static struct rtspcl_data * rtspcl_open(void) { struct rtspcl_data *rtspcld; rtspcld = malloc(sizeof(struct rtspcl_data)); memset(rtspcld, 0, sizeof(struct rtspcl_data)); rtspcld->useragent = "RTSPClient"; return rtspcld; } static bool rtspcl_remove_all_exthds(struct rtspcl_data *rtspcld) { free_kd(rtspcld->exthds); rtspcld->exthds = NULL; return true; } static bool rtspcl_disconnect(struct rtspcl_data *rtspcld) { if (rtspcld->fd > 0) close(rtspcld->fd); rtspcld->fd = 0; return true; } static bool rtspcl_set_useragent(struct rtspcl_data *rtspcld, const char *name) { rtspcld->useragent = name; return true; } static bool rtspcl_add_exthds(struct rtspcl_data *rtspcld, const char *key, char *data) { struct key_data *new_kd; new_kd = (struct key_data *) malloc(sizeof(struct key_data)); new_kd->key = malloc(strlen(key) + 1); new_kd->data = malloc(strlen(data) + 1); strcpy((char*)new_kd->key, key); strcpy((char*)new_kd->data, data); new_kd->next = NULL; if (!rtspcld->exthds) { rtspcld->exthds = new_kd; } else { struct key_data *iter = rtspcld->exthds; while (iter->next) { iter = iter->next; } iter->next = new_kd; } return true; } static bool rtspcl_connect(struct rtspcl_data *rtspcld, const char *host, short destport, char *sid) { unsigned short myport = 0; struct sockaddr_in name; socklen_t namelen = sizeof(name); if ((rtspcld->fd = open_tcp_socket(NULL, &myport)) == -1) return -1; if (!get_tcp_connect_by_host(rtspcld->fd, host, destport)) return -1; getsockname(rtspcld->fd, (struct sockaddr*)&name, &namelen); memcpy(&rtspcld->local_addr, &name.sin_addr,sizeof(struct in_addr)); sprintf(rtspcld->url, "rtsp://%s/%s", inet_ntoa(name.sin_addr), sid); getpeername(rtspcld->fd, (struct sockaddr*)&name, &namelen); memcpy(&rtspcld->host_addr, &name.sin_addr, sizeof(struct in_addr)); return true; } static bool rtspcl_announce_sdp(struct rtspcl_data *rtspcld, char *sdp) { return exec_request(rtspcld, "ANNOUNCE", "application/sdp", sdp, 1, NULL, &rtspcld->kd); } static bool rtspcl_setup(struct rtspcl_data *rtspcld, struct key_data **kd) { struct key_data *rkd = NULL, hds; const char delimiters[] = ";"; char *buf = NULL; char *token, *pc; int rval = false; buf = (char *) malloc(256); sprintf(buf, "RTP/AVP/UDP;unicast;interleaved=0-1;mode=record;control_port=%d;timing_port=%d", raop_session->ctrl.port, raop_session->ntp.port); hds.key = (unsigned char*) strdup("Transport"); hds.data = (unsigned char*) buf; hds.next = NULL; buf = NULL; if (!exec_request(rtspcld, "SETUP", NULL, NULL, 1, &hds, &rkd)) return false; free(hds.key); free(hds.data); if (!(rtspcld->session = strdup(kd_lookup(rkd, "Session")))) { g_warning("%s: no session in response\n",__func__); goto erexit; } if (!(rtspcld->transport = kd_lookup(rkd, "Transport"))) { g_warning("%s: no transport in response\n",__func__); goto erexit; } if (!(buf = malloc(strlen(rtspcld->transport) + 1))) { goto erexit; } strcpy(buf, rtspcld->transport); token = strtok(buf, delimiters); rtspcld->server_port = 0; rtspcld->control_port = 0; while (token) { if ((pc = strstr(token, "="))) { *pc = 0; if (!strcmp(token,"server_port")) { rtspcld->server_port=atoi(pc + 1); } if (!strcmp(token,"control_port")) { rtspcld->control_port=atoi(pc + 1); } } token = strtok(NULL, delimiters); } if (rtspcld->server_port == 0) { g_warning("%s: no server_port in response\n",__func__); goto erexit; } if (rtspcld->control_port == 0) { g_warning("%s: no control_port in response\n",__func__); goto erexit; } rval = true; erexit: if (buf) free(buf); if (!rval) { free_kd(rkd); rkd = NULL; } *kd = rkd; return rval; } static bool rtspcl_record(struct rtspcl_data *rtspcld) { struct key_data *kdRange, *kdRtp; int rval; unsigned char *buf = (unsigned char *) malloc(128); if (!rtspcld->session) { g_warning("%s: no session in progress\n", __func__); free(buf); return false; } sprintf((char *) buf, "seq=%d,rtptime=%u", raop_session->play_state.seq_num, raop_session->play_state.rtptime); kdRange = malloc(sizeof(struct key_data)); kdRtp = malloc(sizeof(struct key_data)); kdRange->key = (unsigned char*) strdup("Range"); kdRange->data = (unsigned char*) strdup("npt=0-"); kdRange->next = kdRtp; kdRtp->key = (unsigned char*) strdup("RTP-Info"); kdRtp->data = buf; kdRtp->next = NULL; rval = exec_request(rtspcld, "RECORD", NULL, NULL, 1, kdRange, &rtspcld->kd); free_kd(kdRange); return rval; } static bool rtspcl_close(struct rtspcl_data *rtspcld) { rtspcl_disconnect(rtspcld); rtspcl_remove_all_exthds(rtspcld); free(rtspcld->session); free(rtspcld); return true; } static char* rtspcl_local_ip(struct rtspcl_data *rtspcld) { return inet_ntoa(rtspcld->local_addr); } static int rsa_encrypt(const unsigned char *text, int len, unsigned char *res) { RSA *rsa; gsize usize; unsigned char *modulus; unsigned char *exponent; int size; char n[] = "59dE8qLieItsH1WgjrcFRKj6eUWqi+bGLOX1HL3U3GhC/j0Qg90u3sG/1CUtwC" "5vOYvfDmFI6oSFXi5ELabWJmT2dKHzBJKa3k9ok+8t9ucRqMd6DZHJ2YCCLlDR" "KSKv6kDqnw4UwPdpOMXziC/AMj3Z/lUVX1G7WSHCAWKf1zNS1eLvqr+boEjXuB" "OitnZ/bDzPHrTOZz0Dew0uowxf/+sG+NCK3eQJVxqcaJ/vEHKIVd2M+5qL71yJ" "Q+87X6oV3eaYvt3zWZYD6z5vYTcrtij2VZ9Zmni/UAaHqn9JdsBWLUEpVviYnh" "imNVvYFZeCXg/IdTQ+x4IRdiXNv5hEew=="; char e[] = "AQAB"; rsa = RSA_new(); modulus = g_base64_decode(n, &usize); rsa->n = BN_bin2bn(modulus, usize, NULL); exponent = g_base64_decode(e, &usize); rsa->e = BN_bin2bn(exponent, usize, NULL); g_free(modulus); g_free(exponent); size = RSA_public_encrypt(len, text, res, rsa, RSA_PKCS1_OAEP_PADDING); RSA_free(rsa); return size; } static int raop_encrypt(struct encrypt_data *encryp, unsigned char *data, int size) { // any bytes that fall beyond the last 16 byte page should be sent // in the clear int alt_size = size - (size % 16); memcpy(encryp->nv, encryp->iv, 16); AES_cbc_encrypt(data, data, alt_size, &encryp->ctx, encryp->nv, 1); return size; } /* write bits filed data, *bpos=0 for msb, *bpos=7 for lsb d=data, blen=length of bits field */ static inline void bits_write(unsigned char **p, unsigned char d, int blen, int *bpos) { int lb, rb, bd; lb =7 - *bpos; rb = lb - blen + 1; if (rb >= 0) { bd = d << rb; if (*bpos) **p |= bd; else **p = bd; *bpos += blen; } else { bd = d >> -rb; **p |= bd; *p += 1; **p = d << (8 + rb); *bpos = -rb; } } static bool wrap_pcm(unsigned char *buffer, int bsize, int *size, unsigned char *inData, int inSize) { unsigned char one[4]; int count = 0; int bpos = 0; unsigned char *bp = buffer; int i, nodata = 0; bits_write(&bp, 1, 3, &bpos); // channel=1, stereo bits_write(&bp, 0, 4, &bpos); // unknown bits_write(&bp, 0, 8, &bpos); // unknown bits_write(&bp, 0, 4, &bpos); // unknown if (bsize != 4096 && false) bits_write(&bp, 1, 1, &bpos); // hassize else bits_write(&bp, 0, 1, &bpos); // hassize bits_write(&bp, 0, 2, &bpos); // unused bits_write(&bp, 1, 1, &bpos); // is-not-compressed if (bsize != 4096 && false) { // size of data, integer, big endian bits_write(&bp, (bsize >> 24) & 0xff, 8, &bpos); bits_write(&bp, (bsize >> 16) & 0xff, 8, &bpos); bits_write(&bp, (bsize >> 8) & 0xff, 8, &bpos); bits_write(&bp, bsize&0xff, 8, &bpos); } while (1) { if (inSize <= count * 4) nodata = 1; if (nodata) break; one[0] = inData[count * 4]; one[1] = inData[count * 4 + 1]; one[2] = inData[count * 4 + 2]; one[3] = inData[count * 4 + 3]; #if BYTE_ORDER == BIG_ENDIAN bits_write(&bp, one[0], 8, &bpos); bits_write(&bp, one[1], 8, &bpos); bits_write(&bp, one[2], 8, &bpos); bits_write(&bp, one[3], 8, &bpos); #else bits_write(&bp, one[1], 8, &bpos); bits_write(&bp, one[0], 8, &bpos); bits_write(&bp, one[3], 8, &bpos); bits_write(&bp, one[2], 8, &bpos); #endif if (++count == bsize) break; } if (!count) return false; // when no data at all, it should stop playing /* when readable size is less than bsize, fill 0 at the bottom */ for(i = 0; i < (bsize - count) * 4; i++) { bits_write(&bp, 0, 8, &bpos); } *size = (int)(bp - buffer); if (bpos) *size += 1; return true; } static bool raopcl_stream_connect(G_GNUC_UNUSED struct raop_data *rd) { return true; } static bool raopcl_connect(struct raop_data *rd) { unsigned char buf[4 + 8 + 16]; char sid[16]; char sci[24]; char act_r[17]; char *sac=NULL, *key = NULL, *iv = NULL; char sdp[1024]; int rval = false; struct key_data *setup_kd = NULL; char *aj, *token, *pc; const char delimiters[] = ";"; unsigned char rsakey[512]; struct timeval current_time; unsigned int sessionNum; int i; gettimeofday(¤t_time,NULL); sessionNum = current_time.tv_sec + 2082844804; RAND_bytes(buf, sizeof(buf)); sprintf(act_r, "%u", (unsigned int) g_random_int()); sprintf(sid, "%u", sessionNum); sprintf(sci, "%08x%08x", *((int *)(buf + 4)), *((int *)(buf + 8))); sac = g_base64_encode(buf + 12, 16); if (!(rd->rtspcl = rtspcl_open())) goto erexit; if (!rtspcl_set_useragent(rd->rtspcl, "iTunes/8.1.1 (Macintosh; U; PPC Mac OS X 10.4)")) goto erexit; if (!rtspcl_add_exthds(rd->rtspcl, "Client-Instance", sci)) goto erexit; if (!rtspcl_add_exthds(rd->rtspcl, "DACP-ID", sci)) goto erexit; if (!rtspcl_add_exthds(rd->rtspcl, "Active-Remote", act_r)) goto erexit; if (!rtspcl_connect(rd->rtspcl, rd->addr, rd->rtsp_port, sid)) goto erexit; i = rsa_encrypt(raop_session->encrypt.key, 16, rsakey); key = g_base64_encode(rsakey, i); remove_char_from_string(key, '='); iv = g_base64_encode(raop_session->encrypt.iv, 16); remove_char_from_string(iv, '='); sprintf(sdp, "v=0\r\n" "o=iTunes %s 0 IN IP4 %s\r\n" "s=iTunes\r\n" "c=IN IP4 %s\r\n" "t=0 0\r\n" "m=audio 0 RTP/AVP 96\r\n" "a=rtpmap:96 AppleLossless\r\n" "a=fmtp:96 %d 0 16 40 10 14 2 255 0 0 44100\r\n" "a=rsaaeskey:%s\r\n" "a=aesiv:%s\r\n", sid, rtspcl_local_ip(rd->rtspcl), rd->addr, NUMSAMPLES, key, iv); remove_char_from_string(sac, '='); // if (!rtspcl_add_exthds(rd->rtspcl, "Apple-Challenge", sac)) goto erexit; if (!rtspcl_announce_sdp(rd->rtspcl, sdp)) goto erexit; // if (!rtspcl_mark_del_exthds(rd->rtspcl, "Apple-Challenge")) goto erexit; if (!rtspcl_setup(rd->rtspcl, &setup_kd)) goto erexit; if (!(aj = kd_lookup(setup_kd,"Audio-Jack-Status"))) { g_warning("%s: Audio-Jack-Status is missing\n",__func__); goto erexit; } token = strtok(aj, delimiters); while (token) { if ((pc = strstr(token,"="))) { *pc = 0; if (!strcmp(token,"type") && !strcmp(pc+1,"digital")) { // rd->ajtype = JACK_TYPE_DIGITAL; } } else { if (!strcmp(token,"connected")) { // rd->ajstatus = JACK_STATUS_CONNECTED; } } token = strtok(NULL, delimiters); } if (!get_sockaddr_by_host(rd->addr, rd->rtspcl->control_port, &rd->ctrl_addr)) goto erexit; if (!get_sockaddr_by_host(rd->addr, rd->rtspcl->server_port, &rd->data_addr)) goto erexit; if (!rtspcl_record(rd->rtspcl)) goto erexit; if (!raopcl_stream_connect(rd)) goto erexit; rval = true; erexit: if (sac) g_free(sac); if (key) g_free(key); if (iv) g_free(iv); free_kd(setup_kd); return rval; } static bool raopcl_close(struct raop_data *rd) { if (rd->rtspcl) rtspcl_close(rd->rtspcl); rd->rtspcl = NULL; free(rd); return true; } static int difference (struct timeval *t1, struct timeval *t2) { int ret = 150000000; if (t1->tv_sec - t2->tv_sec < 150) { ret = (t1->tv_sec - t2->tv_sec) * 1000000; ret += t1->tv_usec - t2->tv_usec; } return ret; } /* * With airtunes version 2, we don't get responses back when we send audio * data. The only requests we get from the airtunes device are timing * requests. */ static bool send_audio_data(int fd) { int i = 0; struct timeval current_time, tout, rtp_time; int diff, olddiff; struct raop_data *rd = raop_session->raop_list; get_time_for_rtp(&raop_session->play_state, &rtp_time); gettimeofday(¤t_time, NULL); olddiff = diff = difference(¤t_time, &rtp_time); while (diff < -10000) { tout.tv_sec = 0; tout.tv_usec = -diff; check_timing(&tout); gettimeofday(¤t_time, NULL); diff = difference(¤t_time, &rtp_time); } gettimeofday(&raop_session->play_state.last_send, NULL); while (rd) { if (rd->started) { raop_session->data[1] = 0x60; } else { rd->started = true; raop_session->data[1] = 0xe0; } i = sendto(fd, raop_session->data + raop_session->wblk_wsize, raop_session->wblk_remsize, 0, (struct sockaddr *) &rd->data_addr, sizeof(rd->data_addr)); if (i < 0) { g_warning("%s: write error: %s\n", __func__, strerror(errno)); return false; } if (i == 0) { g_warning("%s: write, disconnected on the other end\n", __func__); return false; } rd = rd->next; } raop_session->wblk_wsize += i; raop_session->wblk_remsize -= i; //g_debug("%d bytes are sent, remaining size=%d\n",i,rd->wblk_remsize); return true; } static bool raop_output_test_default_device(void) { return false; } static void * raop_output_init(G_GNUC_UNUSED const struct audio_format *audio_format, G_GNUC_UNUSED const struct config_param *param, G_GNUC_UNUSED GError **error) { struct raop_data *rd; rd = new_raop_data(); rd->addr = config_get_block_string(param, "host", NULL); rd->rtsp_port = config_get_block_unsigned(param, "port", 5000); rd->volume = config_get_block_unsigned(param, "volume", 75); return rd; } static bool raop_set_volume_local(struct raop_data *rd, int volume) { char vol_str[128]; sprintf(vol_str, "volume: %d.000000\r\n", volume); return rtspcl_set_parameter(rd->rtspcl, vol_str); } static void raop_output_finish(void *data) { struct raop_data *rd = data; raopcl_close(rd); pthread_mutex_destroy(&rd->control_mutex); } #define RAOP_VOLUME_MIN -30 #define RAOP_VOLUME_MAX 0 int raop_get_volume(struct raop_data *rd) { return rd->volume; } bool raop_set_volume(struct raop_data *rd, unsigned volume) { int raop_volume; bool rval; //set parameter volume if (volume == 0) { raop_volume = -144; } else { raop_volume = RAOP_VOLUME_MIN + (RAOP_VOLUME_MAX - RAOP_VOLUME_MIN) * volume / 100; } pthread_mutex_lock(&rd->control_mutex); rval = raop_set_volume_local(rd, raop_volume); if (rval) rd->volume = volume; pthread_mutex_unlock(&rd->control_mutex); return rval; } static void raop_output_cancel(void *data) { //flush struct key_data kd; struct raop_data *rd = (struct raop_data *) data; unsigned char *buf; int flush_diff = 1; rd->started = 0; if (rd->is_master) { raop_session->play_state.playing = false; } if (rd->paused) { return; } buf = malloc(128); pthread_mutex_lock(&rd->control_mutex); kd.key = (unsigned char *)strdup("RTP-Info"); sprintf((char *) buf, "seq=%d; rtptime=%d", raop_session->play_state.seq_num + flush_diff, raop_session->play_state.rtptime + NUMSAMPLES * flush_diff); kd.data = (unsigned char *)buf; kd.next = NULL; exec_request(rd->rtspcl, "FLUSH", NULL, NULL, 1, &kd, &(rd->rtspcl->kd)); free(kd.key); free(kd.data); pthread_mutex_unlock(&rd->control_mutex); } static bool raop_output_pause(void *data) { struct timeval tout = {.tv_sec = 0, .tv_usec = 0}; struct raop_data *rd = (struct raop_data *) data; check_timing(&tout); rd->paused = true; return true; } static void raop_output_close(void *data) { //teardown struct raop_data *rd = data; struct raop_data *iter = raop_session->raop_list; struct raop_data *prev = NULL; pthread_mutex_lock(&raop_session->list_mutex); while (iter) { if (iter == rd) { if (prev != NULL) { prev->next = rd->next; } else { raop_session->raop_list = rd->next; if (raop_session->raop_list == NULL) { // TODO clean up everything else raop_session->play_state.playing = false; close(raop_session->data_fd); close(raop_session->ntp.fd); close(raop_session->ctrl.fd); } } if (rd->is_master && raop_session->raop_list) { raop_session->raop_list->is_master = true; } rd->next = NULL; rd->is_master = false; break; } prev = iter; iter = iter->next; } pthread_mutex_unlock(&raop_session->list_mutex); pthread_mutex_lock(&rd->control_mutex); exec_request(rd->rtspcl, "TEARDOWN", NULL, NULL, 0, NULL, &(rd->rtspcl->kd)); pthread_mutex_unlock(&rd->control_mutex); rd->started = 0; } static bool raop_output_open(void *data, struct audio_format *audio_format, GError **error_r) { //setup, etc. struct raop_data *rd = data; pthread_mutex_lock(&raop_session->list_mutex); if (raop_session->raop_list == NULL) { // first raop, need to initialize session data unsigned short myport = 0; raop_session->raop_list = rd; rd->is_master = true; if ((raop_session->data_fd = open_udp_socket(NULL, &myport)) == -1) return -1; if ((raop_session->ntp.fd = open_udp_socket(NULL, &raop_session->ntp.port)) == -1) return false; if ((raop_session->ctrl.fd = open_udp_socket(NULL, &raop_session->ctrl.port)) == -1) { close(raop_session->ntp.fd); raop_session->ctrl.fd = -1; return false; } } pthread_mutex_unlock(&raop_session->list_mutex); audio_format->format = SAMPLE_FORMAT_S16; g_debug("raop_openDevice %s %d\n", rd->addr, rd->rtsp_port); if (!raopcl_connect(rd)) { g_set_error(error_r, raop_output_quark(), -1, "Unable to connect to device"); return false; } if (!raop_set_volume(rd, rd->volume)) { g_set_error(error_r, raop_output_quark(), -1, "Unable to set volume after connecting to device"); return false; } pthread_mutex_lock(&raop_session->list_mutex); if (!rd->is_master) { rd->next = raop_session->raop_list; raop_session->raop_list = rd; } pthread_mutex_unlock(&raop_session->list_mutex); return true; } static size_t raop_output_play(void *data, const void *chunk, size_t size, GError **error_r) { //raopcl_send_sample struct raop_data *rd = data; struct timeval tout = {.tv_sec = 0, .tv_usec = 0}; size_t rval = 0, orig_size = size; bool first = false; rd->paused = false; if (!rd->is_master) { // only process data for the master raop return size; } pthread_mutex_lock(&raop_session->data_mutex); check_timing(&tout); if (raop_session->play_state.rtptime <= NUMSAMPLES) { // looped over, need new reference point to calculate correct times raop_session->play_state.playing = false; } first = !raop_session->play_state.playing; while (raop_session->bufferSize + size >= RAOP_BUFFER_SIZE) { // ntp header unsigned char header[] = { 0x80, 0x60, 0x00, 0x00, // rtptime 0x00, 0x00, 0x00, 0x00, // device 0x7e, 0xad, 0xd2, 0xd3, }; int count = 0; int copyBytes = RAOP_BUFFER_SIZE - raop_session->bufferSize; if (!raop_session->play_state.playing || raop_session->play_state.seq_num % (44100 / NUMSAMPLES + 1) == 0) { struct raop_data *iter; pthread_mutex_lock(&raop_session->list_mutex); if (!raop_session->play_state.playing) { gettimeofday(&raop_session->play_state.start_time,NULL); } iter = raop_session->raop_list; while (iter) { if (!send_control_command(&raop_session->ctrl, iter, &raop_session->play_state)) { g_set_error(error_r, raop_output_quark(), -1, "Unable to send control command"); goto erexit; } iter = iter->next; } pthread_mutex_unlock(&raop_session->list_mutex); } fill_int(header + 8, raop_session->play_state.sync_src); memcpy(raop_session->buffer + raop_session->bufferSize, chunk, copyBytes); raop_session->bufferSize += copyBytes; chunk = ((const char *)chunk) + copyBytes; size -= copyBytes; if (!wrap_pcm(raop_session->data + RAOP_HEADER_SIZE, NUMSAMPLES, &count, raop_session->buffer, RAOP_BUFFER_SIZE)) { g_warning("unable to encode %d bytes properly\n", RAOP_BUFFER_SIZE); } memcpy(raop_session->data, header, RAOP_HEADER_SIZE); raop_session->data[2] = raop_session->play_state.seq_num >> 8; raop_session->data[3] = raop_session->play_state.seq_num & 0xff; raop_session->play_state.seq_num ++; fill_int(raop_session->data + 4, raop_session->play_state.rtptime); raop_session->play_state.rtptime += NUMSAMPLES; raop_encrypt(&raop_session->encrypt, raop_session->data + RAOP_HEADER_SIZE, count); raop_session->wblk_remsize = count + RAOP_HEADER_SIZE; raop_session->wblk_wsize = 0; if (!send_audio_data(raop_session->data_fd)) { g_set_error(error_r, raop_output_quark(), -1, "Unable to write to device"); goto erexit; } raop_session->bufferSize = 0; } if (size > 0) { memcpy(raop_session->buffer + raop_session->bufferSize, chunk, size); raop_session->bufferSize += size; } rval = orig_size; erexit: pthread_mutex_unlock(&raop_session->data_mutex); return rval; } const struct audio_output_plugin raopPlugin = { .name = "raop", .test_default_device = raop_output_test_default_device, .init = raop_output_init, .finish = raop_output_finish, .open = raop_output_open, .play = raop_output_play, .cancel = raop_output_cancel, .pause = raop_output_pause, .close = raop_output_close, .mixer_plugin = &raop_mixer_plugin, };