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UxPlay/lib/raop_rtp.c
F. Duncanh d01c27d62a cleanup new rtp to ntp conversion
2025-02-01 01:21:06 -05:00

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/**
* Copyright (C) 2011-2012 Juho Vähä-Herttua
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
*=================================================================
* modified by fduncanh 2021-2023
*/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <errno.h>
#include <stdbool.h>
#include "raop_rtp.h"
#include "raop.h"
#include "raop_buffer.h"
#include "netutils.h"
#include "compat.h"
#include "logger.h"
#include "byteutils.h"
#include "mirror_buffer.h"
#include "stream.h"
#include "utils.h"
#define NO_FLUSH (-42)
#define SECOND_IN_NSECS 1000000000
#define SEC SECOND_IN_NSECS
#define DELAY_AAC 0.20 //empirical, matches audio latency of about -0.25 sec after first clock sync event
/* note: it is unclear what will happen in the unlikely event that this code is running at the time of the unix-time
* epoch event on 2038-01-19 at 3:14:08 UTC ! (but Apple will surely have removed AirPlay "legacy pairing" by then!) */
typedef struct raop_rtp_sync_data_s {
uint64_t ntp_time; // The local wall clock time (unix time in usec) at the time of rtp_time
uint64_t rtp_time; // The remote rtp clock time corresponding to ntp_time
} raop_rtp_sync_data_t;
struct raop_rtp_s {
logger_t *logger;
raop_callbacks_t callbacks;
// Time and sync
raop_ntp_t *ntp;
double rtp_clock_rate;
uint64_t ntp_start_time;
uint64_t rtp_start_time;
uint64_t rtp_time;
bool rtp_clock_started;
uint32_t rtp_sync;
uint64_t client_ntp_sync;
bool initial_sync;
// Transmission Stats, could be used if a playout buffer is needed
// float interarrival_jitter; // As defined by RTP RFC 3550, Section 6.4.1
// unsigned int last_packet_transit_time;
//int transit = (packet_receive_time - packet_send_time);
// int d = transit - last_packet_transit_time;
// if (d < 0) d = -d;
// interarrival_jitter = (1.f / 16.f) * ((double) d - interarrival_jitter);
/* Buffer to handle all resends */
raop_buffer_t *buffer;
/* Remote address as sockaddr */
struct sockaddr_storage remote_saddr;
socklen_t remote_saddr_len;
/* MUTEX LOCKED VARIABLES START */
/* These variables only edited mutex locked */
int running;
int joined;
float volume;
int volume_changed;
unsigned char *metadata;
int metadata_len;
unsigned char *coverart;
int coverart_len;
char *dacp_id;
char *active_remote_header;
unsigned int progress_start;
unsigned int progress_curr;
unsigned int progress_end;
int progress_changed;
int flush;
thread_handle_t thread;
mutex_handle_t run_mutex;
/* MUTEX LOCKED VARIABLES END */
/* Remote control and timing ports */
unsigned short control_rport;
/* Sockets for control and data */
int csock, dsock;
/* Local control, timing and data ports */
unsigned short control_lport;
unsigned short data_lport;
/* Initialized after the first control packet */
struct sockaddr_storage control_saddr;
socklen_t control_saddr_len;
unsigned short control_seqnum;
/* audio compression type: ct = 2 (ALAC), ct = 8 (AAC_ELD) (ct = 4 would be AAC-MAIN) */
unsigned char ct;
};
static int
raop_rtp_parse_remote(raop_rtp_t *raop_rtp, const char *remote, int remotelen)
{
int family;
int ret;
assert(raop_rtp);
if (remotelen == 4) {
family = AF_INET;
} else if (remotelen == 16) {
family = AF_INET6;
} else {
return -1;
}
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp parse remote ip = %s", remote);
ret = netutils_parse_address(family, remote,
&raop_rtp->remote_saddr,
sizeof(raop_rtp->remote_saddr));
if (ret < 0) {
return -1;
}
raop_rtp->remote_saddr_len = ret;
return 0;
}
raop_rtp_t *
raop_rtp_init(logger_t *logger, raop_callbacks_t *callbacks, raop_ntp_t *ntp, const char *remote,
int remotelen, const unsigned char *aeskey, const unsigned char *aesiv)
{
raop_rtp_t *raop_rtp;
assert(logger);
assert(callbacks);
raop_rtp = calloc(1, sizeof(raop_rtp_t));
if (!raop_rtp) {
return NULL;
}
raop_rtp->logger = logger;
raop_rtp->ntp = ntp;
raop_rtp->rtp_sync = 0;
raop_rtp->client_ntp_sync = 0;
raop_rtp->initial_sync = false;
raop_rtp->ntp_start_time = 0;
raop_rtp->rtp_start_time = 0;
raop_rtp->rtp_clock_started = false;
raop_rtp->dacp_id = NULL;
raop_rtp->active_remote_header = NULL;
raop_rtp->metadata = NULL;
raop_rtp->coverart = NULL;
memcpy(&raop_rtp->callbacks, callbacks, sizeof(raop_callbacks_t));
raop_rtp->buffer = raop_buffer_init(logger, aeskey, aesiv);
if (!raop_rtp->buffer) {
free(raop_rtp);
return NULL;
}
if (raop_rtp_parse_remote(raop_rtp, remote, remotelen) < 0) {
free(raop_rtp);
return NULL;
}
raop_rtp->running = 0;
raop_rtp->joined = 1;
raop_rtp->flush = NO_FLUSH;
MUTEX_CREATE(raop_rtp->run_mutex);
return raop_rtp;
}
void
raop_rtp_destroy(raop_rtp_t *raop_rtp)
{
if (raop_rtp) {
raop_rtp_stop(raop_rtp);
MUTEX_DESTROY(raop_rtp->run_mutex);
raop_buffer_destroy(raop_rtp->buffer);
free(raop_rtp->metadata);
free(raop_rtp->coverart);
free(raop_rtp->dacp_id);
free(raop_rtp->active_remote_header);
free(raop_rtp);
}
}
static int
raop_rtp_resend_callback(void *opaque, unsigned short seqnum, unsigned short count)
{
raop_rtp_t *raop_rtp = opaque;
unsigned char packet[8];
unsigned short ourseqnum;
struct sockaddr *addr;
socklen_t addrlen;
int ret;
addr = (struct sockaddr *)&raop_rtp->control_saddr;
addrlen = raop_rtp->control_saddr_len;
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp got resend request %d %d", seqnum, count);
ourseqnum = raop_rtp->control_seqnum++;
/* Fill the request buffer */
packet[0] = 0x80;
packet[1] = 0x55|0x80;
packet[2] = (ourseqnum >> 8);
packet[3] = ourseqnum;
packet[4] = (seqnum >> 8);
packet[5] = seqnum;
packet[6] = (count >> 8);
packet[7] = count;
ret = sendto(raop_rtp->csock, (const char *)packet, sizeof(packet), 0, addr, addrlen);
if (ret == -1) {
logger_log(raop_rtp->logger, LOGGER_WARNING, "raop_rtp resend failed: %d", SOCKET_GET_ERROR());
}
return 0;
}
static int
raop_rtp_init_sockets(raop_rtp_t *raop_rtp, int use_ipv6)
{
assert(raop_rtp);
unsigned short cport = raop_rtp->control_lport;
unsigned short dport = raop_rtp->data_lport;
int csock = netutils_init_socket(&cport, use_ipv6, 1);
int dsock = netutils_init_socket(&dport, use_ipv6, 1);
if (csock == -1 || dsock == -1) {
goto sockets_cleanup;
}
/* Set socket descriptors */
raop_rtp->csock = csock;
raop_rtp->dsock = dsock;
/* Set port values */
raop_rtp->control_lport = cport;
raop_rtp->data_lport = dport;
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp local control port socket %d port UDP %d", csock, cport);
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp local data port socket %d port UDP %d", dsock, dport);
return 0;
sockets_cleanup:
if (csock != -1) closesocket(csock);
if (dsock != -1) closesocket(dsock);
return -1;
}
static int
raop_rtp_process_events(raop_rtp_t *raop_rtp, void *cb_data)
{
int flush;
float volume;
int volume_changed;
unsigned char *metadata;
int metadata_len;
unsigned char *coverart;
int coverart_len;
char *dacp_id;
char *active_remote_header;
unsigned int progress_start;
unsigned int progress_curr;
unsigned int progress_end;
int progress_changed;
assert(raop_rtp);
MUTEX_LOCK(raop_rtp->run_mutex);
if (!raop_rtp->running) {
MUTEX_UNLOCK(raop_rtp->run_mutex);
return 1;
}
/* Read the volume level */
volume = raop_rtp->volume;
volume_changed = raop_rtp->volume_changed;
raop_rtp->volume_changed = 0;
/* Read the flush value */
flush = raop_rtp->flush;
raop_rtp->flush = NO_FLUSH;
/* Read the metadata */
metadata = raop_rtp->metadata;
metadata_len = raop_rtp->metadata_len;
raop_rtp->metadata = NULL;
raop_rtp->metadata_len = 0;
/* Read the coverart */
coverart = raop_rtp->coverart;
coverart_len = raop_rtp->coverart_len;
raop_rtp->coverart = NULL;
raop_rtp->coverart_len = 0;
/* Read DACP remote control data */
dacp_id = raop_rtp->dacp_id;
active_remote_header = raop_rtp->active_remote_header;
raop_rtp->dacp_id = NULL;
raop_rtp->active_remote_header = NULL;
/* Read the progress values */
progress_start = raop_rtp->progress_start;
progress_curr = raop_rtp->progress_curr;
progress_end = raop_rtp->progress_end;
progress_changed = raop_rtp->progress_changed;
raop_rtp->progress_changed = 0;
MUTEX_UNLOCK(raop_rtp->run_mutex);
/* Call set_volume callback if changed */
if (volume_changed) {
//raop_buffer_flush(raop_rtp->buffer, flush); /* seems to be unnecessary, may cause audio artefacts */
if (raop_rtp->callbacks.audio_set_volume) {
raop_rtp->callbacks.audio_set_volume(raop_rtp->callbacks.cls, volume);
}
}
/* Handle flush if requested */
if (flush != NO_FLUSH) {
if (raop_rtp->callbacks.audio_flush) {
raop_rtp->callbacks.audio_flush(raop_rtp->callbacks.cls);
}
}
if (metadata != NULL) {
if (raop_rtp->callbacks.audio_set_metadata) {
raop_rtp->callbacks.audio_set_metadata(raop_rtp->callbacks.cls, metadata, metadata_len);
}
free(metadata);
metadata = NULL;
}
if (coverart != NULL) {
if (raop_rtp->callbacks.audio_set_coverart) {
raop_rtp->callbacks.audio_set_coverart(raop_rtp->callbacks.cls, coverart, coverart_len);
}
free(coverart);
coverart = NULL;
}
if (dacp_id && active_remote_header) {
if (raop_rtp->callbacks.audio_remote_control_id) {
raop_rtp->callbacks.audio_remote_control_id(raop_rtp->callbacks.cls, dacp_id, active_remote_header);
}
free(dacp_id);
free(active_remote_header);
dacp_id = NULL;
active_remote_header = NULL;
}
if (progress_changed) {
if (raop_rtp->callbacks.audio_set_progress) {
raop_rtp->callbacks.audio_set_progress(raop_rtp->callbacks.cls, progress_start, progress_curr, progress_end);
}
}
return 0;
}
static uint64_t rtp_time_to_client_ntp(raop_rtp_t *raop_rtp, uint32_t rtp32) {
if (!raop_rtp->initial_sync) {
return 0;
}
int32_t rtp_change;
rtp32 -= raop_rtp->rtp_sync;
if (rtp32 <= INT32_MAX) {
rtp_change = (int32_t) rtp32;
} else {
rtp_change = -(int32_t) (-rtp32);
}
double incr = raop_rtp->rtp_clock_rate * (double) rtp_change;
incr += (double) raop_rtp->client_ntp_sync;
if (incr < 0.0) {
return 0;
} else {
return (uint64_t) incr;
}
}
static THREAD_RETVAL
raop_rtp_thread_udp(void *arg)
{
raop_rtp_t *raop_rtp = arg;
unsigned char packet[RAOP_PACKET_LEN];
unsigned int packetlen;
struct sockaddr_storage saddr;
socklen_t saddrlen;
bool got_remote_control_saddr = false;
uint64_t video_arrival_offset = 0;
/* initial audio stream has no data */
unsigned char no_data_marker[] = {0x00, 0x68, 0x34, 0x00 };
assert(raop_rtp);
bool logger_debug = (logger_get_level(raop_rtp->logger) >= LOGGER_DEBUG);
raop_rtp->ntp_start_time = raop_ntp_get_local_time();
raop_rtp->rtp_clock_started = false;
int no_resend = (raop_rtp->control_rport == 0); /* true when control_rport is not set */
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp start_time = %8.6f (raop_rtp audio)",
((double) raop_rtp->ntp_start_time) / SEC);
while(1) {
fd_set rfds;
struct timeval tv;
int nfds, ret;
/* Check if we are still running and process callbacks */
if (raop_rtp_process_events(raop_rtp, NULL)) {
break;
}
/* Set timeout value to 5ms */
tv.tv_sec = 0;
tv.tv_usec = 5000;
/* Get the correct nfds value */
nfds = raop_rtp->csock+1;
if (raop_rtp->dsock >= nfds)
nfds = raop_rtp->dsock+1;
/* Set rfds and call select */
FD_ZERO(&rfds);
FD_SET(raop_rtp->csock, &rfds);
FD_SET(raop_rtp->dsock, &rfds);
ret = select(nfds, &rfds, NULL, NULL, &tv);
if (ret == 0) {
/* Timeout happened */
continue;
} else if (ret == -1) {
logger_log(raop_rtp->logger, LOGGER_ERR, "raop_rtp error in select");
break;
}
if (FD_ISSET(raop_rtp->csock, &rfds)) {
if (got_remote_control_saddr== false) {
saddrlen = sizeof(saddr);
packetlen = recvfrom(raop_rtp->csock, (char *)packet, sizeof(packet), 0,
(struct sockaddr *)&saddr, &saddrlen);
if (packetlen > 0) {
memcpy(&raop_rtp->control_saddr, &saddr, saddrlen);
raop_rtp->control_saddr_len = saddrlen;
got_remote_control_saddr = true;
}
} else {
packetlen = recvfrom(raop_rtp->csock, (char *)packet, sizeof(packet), 0, NULL, NULL);
}
int type_c = packet[1] & ~0x80;
logger_log(raop_rtp->logger, LOGGER_DEBUG, "\nraop_rtp type_c 0x%02x, packetlen = %d", type_c, packetlen);
if (type_c == 0x56 && packetlen >= 8) {
/* Handle resent data packet, which begins at offset 4 of these packets */
unsigned char *resent_packet = &packet[4];
unsigned int resent_packetlen = packetlen - 4;
unsigned short seqnum = byteutils_get_short_be(resent_packet, 2);
if (resent_packetlen >= 12) {
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp resent audio packet: seqnum=%u", seqnum);
int result = raop_buffer_enqueue(raop_rtp->buffer, resent_packet, resent_packetlen, 1);
assert(result >= 0);
} else if (logger_debug) {
/* type_c = 0x56 packets with length 8 have been reported */
char *str = utils_data_to_string(packet, packetlen, 16);
logger_log(raop_rtp->logger, LOGGER_DEBUG, "Received empty resent audio packet length %d, seqnum=%u:\n%s",
packetlen, seqnum, str);
free (str);
}
} else if (type_c == 0x54 && packetlen >= 20) {
/* packet[0] = 0x90 (first sync ?) or 0x80 (subsequent ones)
* packet[1] = 0xd4, (0xd4 && ~0x80 = type 0x54)
* packet[2:3] = 0x00 0x04
* packet[4:7] : sync_rtp (big-endian uint32_t)
* packet[8:15]: remote ntp timestamp (big-endian uint64_t)
* packet[16:20]: next_rtp (big-endian uint32_t)
* next_rtp = sync_rtp + 7497 = 441 * 17 (0.17 sec) for AAC-ELD
* next_rtp = sync_rtp + 77175 = 441 * 175 (1.75 sec) for ALAC */
// The unit for the rtp clock is 1 / sample rate = 1 / 44100
uint64_t client_ntp_sync_prev = 0;
uint64_t rtp_sync_prev = 0;
if (!raop_rtp->initial_sync) {
logger_log(raop_rtp->logger, LOGGER_DEBUG, "first audio rtp sync");
raop_rtp->initial_sync = true;
} else {
client_ntp_sync_prev = raop_rtp->client_ntp_sync;
rtp_sync_prev = raop_rtp->rtp_sync;
}
raop_rtp->rtp_sync = byteutils_get_int_be(packet, 4);
uint64_t sync_ntp_raw = byteutils_get_long_be(packet, 8);
raop_rtp->client_ntp_sync = raop_remote_timestamp_to_nano_seconds(raop_rtp->ntp, sync_ntp_raw);
if (logger_debug) {
double offset_change = ((double) raop_rtp->client_ntp_sync) - raop_rtp->rtp_clock_rate * raop_rtp->rtp_sync;
offset_change -= ((double) client_ntp_sync_prev) - raop_rtp->rtp_clock_rate * rtp_sync_prev;
uint64_t sync_ntp_local = raop_ntp_convert_remote_time(raop_rtp->ntp, raop_rtp->rtp_sync);
char *str = utils_data_to_string(packet, packetlen, 20);
logger_log(raop_rtp->logger, LOGGER_DEBUG,
"raop_rtp sync: ntp = %8.6f, ntp_start_time %8.6f\nts_client = %8.6f sync_rtp=%u offset change = %8.6f\n%s",
(double) sync_ntp_local / SEC, (double) raop_rtp->ntp_start_time / SEC,
(double) raop_rtp->client_ntp_sync / SEC, raop_rtp->rtp_sync, offset_change / SEC, str);
free(str);
}
} else if (logger_debug) {
char *str = utils_data_to_string(packet, packetlen, 16);
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp unknown udp control packet\n%s", str);
free(str);
}
}
/* rtp audio data packets:
* packet[0] 0x80
* packet[1] 0x60 = 96
* packet[2:3] seqnum (big-endian unsigned short)
* packet[4:7] rtp timestamp (big-endian unsigned int)
* packet[8:11] 0x00 0x00 0x00 0x00
* packet[12:packetlen - 1] encrypted audio payload
* For (AAC-ELD only), the payload of initial packets at the start of
* the stream may be replaced by a 4-byte "no_data_marker" 0x00 0x68 0x34 0x00 */
/* consecutive AAC-ELD rtp timestamps differ by spf = 480
* consecutive ALAC rtp timestamps differ by spf = 352
* both have PCM uncompressed sampling rate = 441000 Hz */
/* clock time in microseconds advances at (rtp_timestamp * 1000000)/44100 between frames */
/* every AAC-ELD packet is sent three times: 0 0 1 0 1 2 1 2 3 2 3 4 ...
* (after decoding AAC-ELD into PCM, the sound frame is three times bigger)
* ALAC packets are sent once only 0 1 2 3 4 5 ... */
/* When the AAC-ELD audio stream starts, the initial packets are length-16 packets with
* a four-byte "no_data_marker" 0x00 0x68 0x34 0x00 replacing the payload.
* The 12-byte packetheader contains a secnum and rtp_timestamp, and each packets is sent
* three times; the secnum and rtp_timestamp increment according to the same pattern as
* AAC-ELD packets with audio content.*/
/* When the ALAC audio stream starts, the initial packets are length-44 packets with
* the same 32-byte encrypted payload which after decryption is the beginning of a
* 32-byte ALAC packet, presumably with format information, but not actual audio data.
* The secnum and rtp_timestamp in the packet header increment according to the same
* pattern as ALAC packets with audio content */
/* The first ALAC packet with data seems to be decoded just before the first sync event
* so its dequeuing should be delayed until the first rtp sync has occurred */
if (FD_ISSET(raop_rtp->dsock, &rfds)) {
if (!raop_rtp->initial_sync && !video_arrival_offset) {
video_arrival_offset = raop_ntp_get_video_arrival_offset(raop_rtp->ntp);
}
//logger_log(raop_rtp->logger, LOGGER_INFO, "Would have data packet in queue");
// Receiving audio data here
saddrlen = sizeof(saddr);
packetlen = recvfrom(raop_rtp->dsock, (char *)packet, sizeof(packet), 0, NULL, NULL);
// rtp payload type
//int type_d = packet[1] & ~0x80;
//logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp_thread_udp type_d 0x%02x, packetlen = %d", type_d, packetlen);
if (packetlen < 12) {
if (logger_debug) {
char *str = utils_data_to_string(packet, packetlen, 16);
logger_log(raop_rtp->logger, LOGGER_DEBUG, "Received short type_d = 0x%2x packet with length %d:\n%s",
packet[1] & ~0x80, packetlen, str);
free (str);
}
continue;
}
if (!raop_rtp->initial_sync && raop_rtp->ct == 8 && video_arrival_offset) {
/* estimate a fake initial remote timestamp for video synchronization with AAC audio before the first rtp sync */
uint64_t ts = raop_ntp_get_local_time() - video_arrival_offset;
double delay = DELAY_AAC;
ts += (uint64_t) (delay * SEC);
raop_rtp->client_ntp_sync = ts;
raop_rtp->rtp_sync = byteutils_get_int_be(packet, 4);
raop_rtp->initial_sync = true;
}
if (packetlen == 16 && memcmp(packet + 12, no_data_marker, 4) == 0) {
/* this is a "no data" packet */
/* the first such packet could be used to provide the initial rtptime and seqnum formerly given in the RECORD request */
continue;
}
if (raop_rtp->ct == 2 && packetlen == 44) continue; /* ignore the ALAC packets with format information only. */
int result = raop_buffer_enqueue(raop_rtp->buffer, packet, packetlen, 1);
assert(result >= 0);
if (!raop_rtp->initial_sync) {
/* wait until the first sync before dequeing ALAC */
continue;
} else {
// Render continuous buffer entries
void *payload = NULL;
unsigned int payload_size;
unsigned short seqnum;
uint32_t rtp_timestamp;
while ((payload = raop_buffer_dequeue(raop_rtp->buffer, &payload_size, &rtp_timestamp, &seqnum, no_resend))) {
audio_decode_struct audio_data;
audio_data.rtp_time = rtp_timestamp;
audio_data.seqnum = seqnum;
audio_data.data_len = payload_size;
audio_data.data = payload;
audio_data.ct = raop_rtp->ct;
audio_data.ntp_time_remote = rtp_time_to_client_ntp(raop_rtp, rtp_timestamp);
audio_data.ntp_time_local = raop_ntp_convert_remote_time(raop_rtp->ntp, audio_data.ntp_time_remote);
if (logger_debug) {
uint64_t ntp_now = raop_ntp_get_local_time();
int64_t latency = (audio_data.ntp_time_local ? ((int64_t) ntp_now) - ((int64_t) audio_data.ntp_time_local) : 0);
logger_log(raop_rtp->logger, LOGGER_DEBUG,
"raop_rtp audio: now = %8.6f, ntp = %8.6f, latency = %9.6f, ts = %8.6f, rtp_time=%u seqnum = %u",
(double) ntp_now / SEC, (double) audio_data.ntp_time_local / SEC, (double) latency / SEC,
(double) audio_data.ntp_time_remote /SEC, rtp_timestamp, seqnum);
}
raop_rtp->callbacks.audio_process(raop_rtp->callbacks.cls, raop_rtp->ntp, &audio_data);
free(payload);
}
/* Handle possible resend requests */
if (!no_resend) {
raop_buffer_handle_resends(raop_rtp->buffer, raop_rtp_resend_callback, raop_rtp);
}
}
}
}
// Ensure running reflects the actual state
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->running = false;
MUTEX_UNLOCK(raop_rtp->run_mutex);
logger_log(raop_rtp->logger, LOGGER_DEBUG, "raop_rtp exiting thread");
return 0;
}
// Start rtp service, using two udp ports
void
raop_rtp_start_audio(raop_rtp_t *raop_rtp, unsigned short *control_rport, unsigned short *control_lport,
unsigned short *data_lport, unsigned char *ct, unsigned int *sr)
{
logger_log(raop_rtp->logger, LOGGER_INFO, "raop_rtp starting audio");
int use_ipv6 = 0;
assert(raop_rtp);
MUTEX_LOCK(raop_rtp->run_mutex);
if (raop_rtp->running || !raop_rtp->joined) {
MUTEX_UNLOCK(raop_rtp->run_mutex);
return;
}
raop_rtp->ct = *ct;
raop_rtp->rtp_clock_rate = SECOND_IN_NSECS / *sr;
/* Initialize ports and sockets */
raop_rtp->control_lport = *control_lport;
raop_rtp->data_lport = *data_lport;
raop_rtp->control_rport = *control_rport;
if (raop_rtp->remote_saddr.ss_family == AF_INET6) {
use_ipv6 = 1;
}
//use_ipv6 = 0;
if (raop_rtp_init_sockets(raop_rtp, use_ipv6) < 0) {
logger_log(raop_rtp->logger, LOGGER_ERR, "raop_rtp initializing sockets failed");
MUTEX_UNLOCK(raop_rtp->run_mutex);
return;
}
*control_lport = raop_rtp->control_lport;
*data_lport = raop_rtp->data_lport;
/* Create the thread and initialize running values */
raop_rtp->running = 1;
raop_rtp->joined = 0;
THREAD_CREATE(raop_rtp->thread, raop_rtp_thread_udp, raop_rtp);
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_set_volume(raop_rtp_t *raop_rtp, float volume)
{
assert(raop_rtp);
if (volume > 0.0f) {
volume = 0.0f;
} else if (volume < -144.0f) {
volume = -144.0f;
}
/* Set volume in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->volume = volume;
raop_rtp->volume_changed = 1;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_set_metadata(raop_rtp_t *raop_rtp, const char *data, int datalen)
{
unsigned char *metadata;
assert(raop_rtp);
if (datalen <= 0) {
return;
}
metadata = malloc(datalen);
assert(metadata);
memcpy(metadata, data, datalen);
/* Set metadata in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->metadata = metadata;
raop_rtp->metadata_len = datalen;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_set_coverart(raop_rtp_t *raop_rtp, const char *data, int datalen)
{
unsigned char *coverart;
assert(raop_rtp);
if (datalen <= 0) {
return;
}
coverart = malloc(datalen);
assert(coverart);
memcpy(coverart, data, datalen);
/* Set coverart in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->coverart = coverart;
raop_rtp->coverart_len = datalen;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_remote_control_id(raop_rtp_t *raop_rtp, const char *dacp_id, const char *active_remote_header)
{
assert(raop_rtp);
if (!dacp_id || !active_remote_header) {
return;
}
/* Set dacp stuff in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
if (raop_rtp->dacp_id) {
free(raop_rtp->dacp_id);
}
raop_rtp->dacp_id = strdup(dacp_id);
if (raop_rtp->active_remote_header) {
free(raop_rtp->active_remote_header);
}
raop_rtp->active_remote_header = strdup(active_remote_header);
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_set_progress(raop_rtp_t *raop_rtp, unsigned int start, unsigned int curr, unsigned int end)
{
assert(raop_rtp);
/* Set progress in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->progress_start = start;
raop_rtp->progress_curr = curr;
raop_rtp->progress_end = end;
raop_rtp->progress_changed = 1;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_flush(raop_rtp_t *raop_rtp, int next_seq)
{
assert(raop_rtp);
/* Call flush in thread instead */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->flush = next_seq;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
void
raop_rtp_stop(raop_rtp_t *raop_rtp)
{
assert(raop_rtp);
/* Check that we are running and thread is not
* joined (should never be while still running) */
MUTEX_LOCK(raop_rtp->run_mutex);
if (!raop_rtp->running || raop_rtp->joined) {
MUTEX_UNLOCK(raop_rtp->run_mutex);
return;
}
raop_rtp->running = 0;
MUTEX_UNLOCK(raop_rtp->run_mutex);
/* Join the thread */
THREAD_JOIN(raop_rtp->thread);
if (raop_rtp->csock != -1) closesocket(raop_rtp->csock);
if (raop_rtp->dsock != -1) closesocket(raop_rtp->dsock);
/* Flush buffer into initial state */
raop_buffer_flush(raop_rtp->buffer, -1);
/* Mark thread as joined */
MUTEX_LOCK(raop_rtp->run_mutex);
raop_rtp->joined = 1;
MUTEX_UNLOCK(raop_rtp->run_mutex);
}
int
raop_rtp_is_running(raop_rtp_t *raop_rtp)
{
assert(raop_rtp);
MUTEX_LOCK(raop_rtp->run_mutex);
int running = raop_rtp->running;
MUTEX_UNLOCK(raop_rtp->run_mutex);
return running;
}
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