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mpv/libao2/ao_nas.c
2002-02-20 22:45:48 +00:00

504 lines
12 KiB
C

/*
* NAS output plugin for mplayer
*
* based on the libaudiooss parts rewritten by me, which were
* originally based on the NAS output plugin for xmms.
*
* xmms plugin by Willem Monsuwe
* adapted for libaudiooss by Jon Trulson
* further modified by Erik Inge Bolsø
* largely rewritten and used for this
* plugin by Tobias Diedrich
*
*/
#include <stdio.h>
#include <stdlib.h>
#include <pthread.h>
#include <audio/audiolib.h>
#include "audio_out.h"
#include "audio_out_internal.h"
#include "afmt.h"
#define NAS_FRAG_SIZE 4096
#define NAS_FRAG_COUNT 8
#define NAS_BUFFER_SIZE NAS_FRAG_SIZE * NAS_FRAG_COUNT
#define NAS_DEBUG 0
#if NAS_DEBUG == 1
static char *nas_event_types[] = {
"Undefined",
"Undefined",
"ElementNotify",
"GrabNotify",
"MonitorNotify",
"BucketNotify",
"DeviceNotify"
};
static char *nas_elementnotify_kinds[] = {
"LowWater",
"HighWater",
"State",
"Unknown"
};
static char *nas_states[] = {
"Stop",
"Start",
"Pause",
"Any"
};
static char *nas_reasons[] = {
"User",
"Underrun",
"Overrun",
"EOF",
"Watermark",
"Hardware",
"Any"
};
static char* nas_reason(unsigned int reason)
{
if (reason > 6) reason = 6;
return nas_reasons[reason];
}
static char* nas_elementnotify_kind(unsigned int kind)
{
if (kind > 2) kind = 3;
return nas_elementnotify_kinds[kind];
}
static char* nas_event_type(unsigned int type) {
if (type > 6) type = 0;
return nas_event_types[type];
}
static char* nas_state(unsigned int state) {
if (state>3) state = 3;
return nas_states[state];
}
#define DPRINTF(format, args...) fprintf(stderr, format, ## args); \
fflush(stderr)
#else
#define DPRINTF(format, args...)
#endif
static ao_info_t info =
{
"NAS audio output",
"nas",
"Tobias Diedrich",
""
};
struct ao_nas_data {
AuServer *aud;
AuFlowID flow;
AuDeviceID dev;
int flow_stopped;
int flow_paused;
void *client_buffer;
int client_buffer_size;
int client_buffer_used;
int server_buffer_size;
int server_buffer_used;
pthread_mutex_t buffer_mutex;
pthread_t event_thread;
int stop_thread;
};
static struct ao_nas_data *nas_data;
LIBAO_EXTERN(nas)
static void nas_print_error(AuServer *aud, char *prefix, AuStatus as)
{
char s[100];
AuGetErrorText(aud, as, s, 100);
fprintf(stderr, "ao_nas: %s: returned status %d (%s)\n", prefix, as, s);
fflush(stderr);
}
static int nas_readBuffer(struct ao_nas_data *nas_data, int num)
{
AuStatus as;
pthread_mutex_lock(&nas_data->buffer_mutex);
DPRINTF("ao_nas: nas_readBuffer(): num=%d client=%d/%d server=%d/%d\n",
num,
nas_data->client_buffer_used, nas_data->client_buffer_size,
nas_data->server_buffer_used, nas_data->server_buffer_size);
if (nas_data->client_buffer_used == 0) {
DPRINTF("ao_nas: buffer is empty, nothing read.\n");
pthread_mutex_unlock(&nas_data->buffer_mutex);
return 0;
}
if (nas_data->client_buffer_used < num)
num = nas_data->client_buffer_used;
AuWriteElement(nas_data->aud, nas_data->flow, 0, num, nas_data->client_buffer, AuFalse, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "nas_readBuffer(): AuWriteElement", as);
else {
nas_data->client_buffer_used -= num;
nas_data->server_buffer_used += num;
memmove(nas_data->client_buffer, nas_data->client_buffer + num, nas_data->client_buffer_used);
}
pthread_mutex_unlock(&nas_data->buffer_mutex);
if (nas_data->flow_paused) {
AuPauseFlow(nas_data->aud, nas_data->flow, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "nas_readBuffer(): AuPauseFlow", as);
}
return num;
}
static void nas_writeBuffer(struct ao_nas_data *nas_data, void *data, int len)
{
pthread_mutex_lock(&nas_data->buffer_mutex);
DPRINTF("ao_nas: nas_writeBuffer(): len=%d client=%d/%d server=%d/%d\n",
len, nas_data->client_buffer_used, nas_data->client_buffer_size,
nas_data->server_buffer_used, nas_data->server_buffer_size);
memcpy(nas_data->client_buffer + nas_data->client_buffer_used, data, len);
nas_data->client_buffer_used += len;
pthread_mutex_unlock(&nas_data->buffer_mutex);
if (nas_data->server_buffer_used < nas_data->server_buffer_size)
nas_readBuffer(nas_data, nas_data->server_buffer_size - nas_data->server_buffer_used);
}
static int nas_empty_event_queue(struct ao_nas_data *nas_data)
{
AuEvent ev;
int result = 0;
while (AuScanForTypedEvent(nas_data->aud, AuEventsQueuedAfterFlush,
AuTrue, AuEventTypeElementNotify, &ev)) {
AuDispatchEvent(nas_data->aud, &ev);
result = 1;
}
return result;
}
static void *nas_event_thread_start(void *data)
{
struct ao_nas_data *nas_data = data;
AuEvent ev;
AuBool result;
do {
nas_empty_event_queue(nas_data);
usleep(10000);
} while (!nas_data->stop_thread);
}
static AuBool nas_error_handler(AuServer* aud, AuErrorEvent* ev)
{
char s[100];
AuGetErrorText(aud, ev->error_code, s, 100);
fprintf(stderr,"ao_nas: error [%s]\n"
"error_code: %d\n"
"request_code: %d\n"
"minor_code: %d\n",
s,
ev->error_code,
ev->request_code,
ev->minor_code);
fflush(stderr);
return AuTrue;
}
static AuBool nas_event_handler(AuServer *aud, AuEvent *ev, AuEventHandlerRec *hnd)
{
AuElementNotifyEvent *event = (AuElementNotifyEvent *) ev;
AuStatus as;
struct ao_nas_data *nas_data = hnd->data;
switch (ev->type) {
case AuEventTypeElementNotify:
DPRINTF("ao_nas: event_handler(): kind %s state %s->%s reason %s numbytes %d\n",
nas_elementnotify_kind(event->kind),
nas_state(event->prev_state),
nas_state(event->cur_state),
nas_reason(event->reason),
event->num_bytes);
nas_data->server_buffer_used -= event->num_bytes;
if (nas_data->server_buffer_used < 0)
nas_data->server_buffer_used = 0;
switch (event->kind) {
case AuElementNotifyKindLowWater:
nas_readBuffer(nas_data, event->num_bytes);
break;
case AuElementNotifyKindState:
if (event->cur_state == AuStatePause) {
switch (event->reason) {
case AuReasonUnderrun:
// buffer underrun -> refill buffer
nas_data->server_buffer_used = 0;
nas_readBuffer(nas_data, nas_data->server_buffer_size - nas_data->server_buffer_used);
break;
default:
break;
}
}
break;
default: // silently ignored
break;
}
break;
default:
printf("ao_nas: nas_event_handler(): unhandled event type %d\n", ev->type);
break;
}
return AuTrue;
}
static AuDeviceID nas_find_device(AuServer *aud, int nch)
{
int i;
for (i = 0; i < AuServerNumDevices(aud); i++) {
AuDeviceAttributes *dev = AuServerDevice(aud, i);
if ((AuDeviceKind(dev) == AuComponentKindPhysicalOutput) &&
AuDeviceNumTracks(dev) == nch) {
return AuDeviceIdentifier(dev);
}
}
return AuNone;
}
static unsigned char nas_aformat_to_auformat(unsigned int format)
{
switch (format) {
case AFMT_U8: return AuFormatLinearUnsigned8;
case AFMT_S8: return AuFormatLinearSigned8;
case AFMT_U16_LE: return AuFormatLinearUnsigned16LSB;
case AFMT_U16_BE: return AuFormatLinearUnsigned16MSB;
case AFMT_S16_LE: return AuFormatLinearSigned16LSB;
case AFMT_S16_BE: return AuFormatLinearSigned16MSB;
case AFMT_MU_LAW: return AuFormatULAW8;
default: return 0;
}
}
// to set/get/query special features/parameters
static int control(int cmd,int arg){
return -1;
}
// open & setup audio device
// return: 1=success 0=fail
static int init(int rate,int channels,int format,int flags)
{
AuElement elms[3];
AuStatus as;
unsigned char auformat = nas_aformat_to_auformat(format);
int bytes_per_sample = channels * AuSizeofFormat(auformat);
char *server;
nas_data=malloc(sizeof(struct ao_nas_data));
printf("ao2: %d Hz %d chans %s\n",rate,channels,
audio_out_format_name(format));
if (!auformat) {
printf("ao_nas: init(): Unsupported format -> nosound\n");
return 0;
}
nas_data->client_buffer_size = NAS_BUFFER_SIZE;
nas_data->client_buffer = malloc(nas_data->client_buffer_size);
nas_data->server_buffer_size = NAS_BUFFER_SIZE;
ao_data.samplerate = rate;
ao_data.channels = channels;
ao_data.buffersize = NAS_BUFFER_SIZE * 2;
ao_data.outburst = NAS_FRAG_SIZE;
ao_data.bps = rate * bytes_per_sample;
if (!bytes_per_sample) {
printf("ao_nas: init(): Zero bytes per sample -> nosound\n");
return 0;
}
if (!(server = getenv("AUDIOSERVER")))
server = getenv("DISPLAY");
if (!server) // default to tcp/localhost:8000
server = "tcp/localhost:8000";
printf("ao_nas: init(): Using audioserver %s\n", server);
nas_data->aud = AuOpenServer(server, 0, NULL, 0, NULL, NULL);
if (!nas_data->aud){
printf("ao_nas: init(): Can't open nas audio server -> nosound\n");
return 0;
}
nas_data->dev = nas_find_device(nas_data->aud, channels);
if ((nas_data->dev == AuNone) || (!(nas_data->flow = AuCreateFlow(nas_data->aud, NULL)))) {
printf("ao_nas: init(): Can't find a device serving that many channels -> nosound\n");
AuCloseServer(nas_data->aud);
nas_data->aud = 0;
return 0;
}
AuMakeElementImportClient(elms, rate, auformat, channels, AuTrue,
NAS_BUFFER_SIZE / bytes_per_sample,
(NAS_BUFFER_SIZE - NAS_FRAG_SIZE) / bytes_per_sample,
0, NULL);
AuMakeElementExportDevice(elms+1, 0, nas_data->dev, rate,
AuUnlimitedSamples, 0, NULL);
AuSetElements(nas_data->aud, nas_data->flow, AuTrue, 2, elms, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "init(): AuSetElements", as);
AuRegisterEventHandler(nas_data->aud, AuEventHandlerIDMask |
AuEventHandlerTypeMask,
AuEventTypeElementNotify, nas_data->flow,
nas_event_handler, (AuPointer) nas_data);
AuSetErrorHandler(nas_data->aud, nas_error_handler);
nas_data->flow_stopped=1;
pthread_mutex_init(&nas_data->buffer_mutex, NULL);
pthread_create(&nas_data->event_thread, NULL, &nas_event_thread_start, nas_data);
return 1;
}
// close audio device
static void uninit(){
AuStatus as;
nas_data->stop_thread = 1;
pthread_join(nas_data->event_thread, NULL);
if (!nas_data->flow_stopped) {
AuStopFlow(nas_data->aud, nas_data->flow, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "uninit(): AuStopFlow", as);
}
AuCloseServer(nas_data->aud);
nas_data->aud = 0;
free(nas_data->client_buffer);
}
// stop playing and empty buffers (for seeking/pause)
static void reset(){
AuStatus as;
pthread_mutex_lock(&nas_data->buffer_mutex);
nas_data->client_buffer_used = 0;
if (!nas_data->flow_stopped) {
AuStopFlow(nas_data->aud, nas_data->flow, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "reset(): AuStopFlow", as);
nas_data->flow_stopped = 1;
}
nas_data->server_buffer_used = 0;
pthread_mutex_unlock(&nas_data->buffer_mutex);
}
// stop playing, keep buffers (for pause)
static void audio_pause()
{
AuStatus as;
DPRINTF("ao_nas: audio_pause()\n");
nas_data->flow_paused = 1;
}
// resume playing, after audio_pause()
static void audio_resume()
{
AuStatus as;
AuEvent ev;
DPRINTF("ao_nas: audio_resume()\n");
nas_data->flow_stopped = 0;
nas_data->flow_paused = 0;
AuStartFlow(nas_data->aud, nas_data->flow, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "play(): AuStartFlow", as);
}
// return: how many bytes can be played without blocking
static int get_space()
{
int result;
DPRINTF("ao_nas: get_space()\n");
pthread_mutex_lock(&nas_data->buffer_mutex);
result = nas_data->client_buffer_size - nas_data->client_buffer_used;
pthread_mutex_unlock(&nas_data->buffer_mutex);
return result;
}
// plays 'len' bytes of 'data'
// it should round it down to outburst*n
// return: number of bytes played
static int play(void* data,int len,int flags)
{
int maxbursts, playbursts, writelen;
AuStatus as;
DPRINTF("ao_nas: play()\n");
if (nas_data->flow_stopped) {
AuEvent ev;
AuStartFlow(nas_data->aud, nas_data->flow, &as);
if (as != AuSuccess)
nas_print_error(nas_data->aud, "play(): AuStartFlow", as);
nas_data->flow_stopped = 0;
while (!nas_empty_event_queue(nas_data)); // wait for first buffer underrun event
}
pthread_mutex_lock(&nas_data->buffer_mutex);
maxbursts = (nas_data->client_buffer_size -
nas_data->client_buffer_used) / ao_data.outburst;
playbursts = len / ao_data.outburst;
writelen = (playbursts > maxbursts ? maxbursts : playbursts) *
ao_data.outburst;
pthread_mutex_unlock(&nas_data->buffer_mutex);
nas_writeBuffer(nas_data, data, writelen);
return writelen;
}
// return: delay in seconds between first and last sample in buffer
static float get_delay()
{
float result;
DPRINTF("ao_nas: get_delay()\n");
pthread_mutex_lock(&nas_data->buffer_mutex);
result = ((float)(nas_data->client_buffer_used +
nas_data->server_buffer_used)) /
(float)ao_data.bps;
pthread_mutex_unlock(&nas_data->buffer_mutex);
return result;
}