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pipewire/spa/plugins/alsa/alsa-seq.c
Daniel Baumann 6b016a712f
Adding upstream version 1.4.2. 
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
2025-06-22 21:40:42 +02:00

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33 KiB
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/* Spa ALSA Sequencer */
/* SPDX-FileCopyrightText: Copyright © 2019 Wim Taymans */
/* SPDX-License-Identifier: MIT */
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sched.h>
#include <errno.h>
#include <getopt.h>
#include <sys/time.h>
#include <math.h>
#include <limits.h>
#include <spa/utils/result.h>
#include <spa/pod/filter.h>
#include <spa/support/system.h>
#include <spa/control/control.h>
#include <spa/control/ump-utils.h>
#include "alsa.h"
#include "alsa-seq.h"
#define CHECK(s,msg,...) if ((res = (s)) < 0) { spa_log_error(state->log, msg ": %s", ##__VA_ARGS__, snd_strerror(res)); return res; }
static int seq_open(struct seq_state *state, struct seq_conn *conn, bool with_queue, bool probe_ump)
{
struct props *props = &state->props;
int res;
spa_log_debug(state->log, "%p: ALSA seq open '%s' duplex", state, props->device);
if ((res = snd_seq_open(&conn->hndl,
props->device,
SND_SEQ_OPEN_DUPLEX,
0)) < 0)
return res;
if (!state->ump) {
spa_log_info(state->log, "%p: ALSA UMP MIDI disabled", state);
return 0;
}
#ifdef HAVE_ALSA_UMP
res = snd_seq_set_client_midi_version(conn->hndl, SND_SEQ_CLIENT_UMP_MIDI_2_0);
if (!res) {
snd_seq_client_info_t *info = NULL;
/* Double check client version */
res = snd_seq_client_info_malloc(&info);
if (!res)
res = snd_seq_get_client_info(conn->hndl, info);
if (!res) {
res = snd_seq_client_info_get_midi_version(info);
if (res == SND_SEQ_CLIENT_UMP_MIDI_2_0)
res = 0;
else
res = -EIO;
}
if (info)
snd_seq_client_info_free(info);
}
#else
res = -EOPNOTSUPP;
#endif
if (res < 0) {
spa_log_lev(state->log, (probe_ump ? SPA_LOG_LEVEL_INFO : SPA_LOG_LEVEL_ERROR),
"%p: ALSA failed to enable UMP MIDI: %s", state, snd_strerror(res));
if (!probe_ump) {
snd_seq_close(conn->hndl);
return res; /* either all are UMP or none are UMP */
}
state->ump = false;
} else {
spa_log_debug(state->log, "%p: ALSA UMP MIDI enabled", state);
state->ump = true;
}
return 0;
}
static int seq_init(struct seq_state *state, struct seq_conn *conn, bool with_queue)
{
struct pollfd pfd;
snd_seq_port_info_t *pinfo;
int res;
/* client id */
if ((res = snd_seq_client_id(conn->hndl)) < 0) {
spa_log_error(state->log, "failed to get client id: %d", res);
goto error_exit_close;
}
conn->addr.client = res;
/* queue */
if (with_queue) {
if ((res = snd_seq_alloc_queue(conn->hndl)) < 0) {
spa_log_error(state->log, "failed to create queue: %d", res);
goto error_exit_close;
}
conn->queue_id = res;
} else {
conn->queue_id = -1;
}
if ((res = snd_seq_nonblock(conn->hndl, 1)) < 0)
spa_log_warn(state->log, "can't set nonblock mode: %s", snd_strerror(res));
/* port for receiving */
snd_seq_port_info_alloca(&pinfo);
snd_seq_port_info_set_name(pinfo, "input");
snd_seq_port_info_set_type(pinfo, SND_SEQ_PORT_TYPE_MIDI_GENERIC);
snd_seq_port_info_set_capability(pinfo,
SND_SEQ_PORT_CAP_WRITE | SND_SEQ_PORT_CAP_READ);
/* Enable timestamping for events sent by external subscribers. */
snd_seq_port_info_set_timestamping(pinfo, 1);
snd_seq_port_info_set_timestamp_real(pinfo, 1);
if (with_queue)
snd_seq_port_info_set_timestamp_queue(pinfo, conn->queue_id);
if ((res = snd_seq_create_port(conn->hndl, pinfo)) < 0) {
spa_log_error(state->log, "failed to create port: %s", snd_strerror(res));
goto error_exit_close;
}
conn->addr.port = snd_seq_port_info_get_port(pinfo);
spa_log_debug(state->log, "queue:%d client:%d port:%d",
conn->queue_id, conn->addr.client, conn->addr.port);
snd_seq_poll_descriptors(conn->hndl, &pfd, 1, POLLIN);
conn->source.fd = pfd.fd;
conn->source.mask = SPA_IO_IN;
return 0;
error_exit_close:
snd_seq_close(conn->hndl);
return res;
}
static int seq_close(struct seq_state *state, struct seq_conn *conn)
{
int res;
spa_log_debug(state->log, "%p: Device '%s' closing", state, state->props.device);
if ((res = snd_seq_close(conn->hndl)) < 0) {
spa_log_warn(state->log, "close failed: %s", snd_strerror(res));
}
return res;
}
static int init_stream(struct seq_state *state, enum spa_direction direction)
{
struct seq_stream *stream = &state->streams[direction];
int res;
stream->direction = direction;
if (direction == SPA_DIRECTION_INPUT) {
stream->caps = SND_SEQ_PORT_CAP_SUBS_WRITE;
} else {
stream->caps = SND_SEQ_PORT_CAP_SUBS_READ;
}
if ((res = snd_midi_event_new(MAX_EVENT_SIZE, &stream->codec)) < 0) {
spa_log_error(state->log, "can make event decoder: %s",
snd_strerror(res));
return res;
}
snd_midi_event_no_status(stream->codec, 1);
memset(stream->ports, 0, sizeof(stream->ports));
return 0;
}
static int uninit_stream(struct seq_state *state, enum spa_direction direction)
{
struct seq_stream *stream = &state->streams[direction];
if (stream->codec)
snd_midi_event_free(stream->codec);
stream->codec = NULL;
return 0;
}
static void init_ports(struct seq_state *state)
{
snd_seq_addr_t addr;
snd_seq_client_info_t *client_info;
snd_seq_port_info_t *port_info;
snd_seq_client_info_alloca(&client_info);
snd_seq_port_info_alloca(&port_info);
snd_seq_client_info_set_client(client_info, -1);
while (snd_seq_query_next_client(state->sys.hndl, client_info) >= 0) {
addr.client = snd_seq_client_info_get_client(client_info);
if (addr.client == SND_SEQ_CLIENT_SYSTEM ||
addr.client == state->sys.addr.client ||
addr.client == state->event.addr.client)
continue;
snd_seq_port_info_set_client(port_info, addr.client);
snd_seq_port_info_set_port(port_info, -1);
while (snd_seq_query_next_port(state->sys.hndl, port_info) >= 0) {
addr.port = snd_seq_port_info_get_port(port_info);
state->port_info(state->port_info_data, &addr, port_info);
}
}
}
static void debug_event(struct seq_state *state, snd_seq_event_t *ev)
{
if (SPA_LIKELY(!spa_log_level_topic_enabled(state->log, SPA_LOG_TOPIC_DEFAULT, SPA_LOG_LEVEL_TRACE)))
return;
spa_log_trace(state->log, "event type:%d flags:0x%x", ev->type, ev->flags);
switch (ev->flags & SND_SEQ_TIME_STAMP_MASK) {
case SND_SEQ_TIME_STAMP_TICK:
spa_log_trace(state->log, " time: %d ticks", ev->time.tick);
break;
case SND_SEQ_TIME_STAMP_REAL:
spa_log_trace(state->log, " time = %d.%09d",
(int)ev->time.time.tv_sec,
(int)ev->time.time.tv_nsec);
break;
}
spa_log_trace(state->log, " source:%d.%d dest:%d.%d queue:%d",
ev->source.client,
ev->source.port,
ev->dest.client,
ev->dest.port,
ev->queue);
}
#ifdef HAVE_ALSA_UMP
static void debug_ump_event(struct seq_state *state, snd_seq_ump_event_t *ev)
{
if (SPA_LIKELY(!spa_log_level_topic_enabled(state->log, SPA_LOG_TOPIC_DEFAULT, SPA_LOG_LEVEL_TRACE)))
return;
spa_log_trace(state->log, "event type:%d flags:0x%x", ev->type, ev->flags);
switch (ev->flags & SND_SEQ_TIME_STAMP_MASK) {
case SND_SEQ_TIME_STAMP_TICK:
spa_log_trace(state->log, " time: %d ticks", ev->time.tick);
break;
case SND_SEQ_TIME_STAMP_REAL:
spa_log_trace(state->log, " time = %d.%09d",
(int)ev->time.time.tv_sec,
(int)ev->time.time.tv_nsec);
break;
}
spa_log_trace(state->log, " source:%d.%d dest:%d.%d queue:%d",
ev->source.client,
ev->source.port,
ev->dest.client,
ev->dest.port,
ev->queue);
}
#endif
static void alsa_seq_on_sys(struct spa_source *source)
{
struct seq_state *state = source->data;
const bool ump = state->ump;
int res;
while (1) {
const snd_seq_addr_t *addr;
snd_seq_event_type_t type;
if (ump) {
#ifdef HAVE_ALSA_UMP
snd_seq_ump_event_t *ev;
res = snd_seq_ump_event_input(state->sys.hndl, &ev);
if (res <= 0)
break;
debug_ump_event(state, ev);
addr = &ev->data.addr;
type = ev->type;
#else
spa_assert_not_reached();
#endif
} else {
snd_seq_event_t *ev;
res = snd_seq_event_input(state->sys.hndl, &ev);
if (res <= 0)
break;
debug_event(state, ev);
addr = &ev->data.addr;
type = ev->type;
}
if (addr->client == state->event.addr.client)
continue;
switch (type) {
case SND_SEQ_EVENT_CLIENT_START:
case SND_SEQ_EVENT_CLIENT_CHANGE:
spa_log_info(state->log, "client add/change %d", addr->client);
break;
case SND_SEQ_EVENT_CLIENT_EXIT:
spa_log_info(state->log, "client exit %d", addr->client);
break;
case SND_SEQ_EVENT_PORT_START:
case SND_SEQ_EVENT_PORT_CHANGE:
{
snd_seq_port_info_t *info;
snd_seq_port_info_alloca(&info);
if ((res = snd_seq_get_any_port_info(state->sys.hndl,
addr->client, addr->port, info)) < 0) {
spa_log_warn(state->log, "can't get port info %d.%d: %s",
addr->client, addr->port, snd_strerror(res));
} else {
spa_log_info(state->log, "port add/change %d:%d",
addr->client, addr->port);
state->port_info(state->port_info_data, addr, info);
}
break;
}
case SND_SEQ_EVENT_PORT_EXIT:
spa_log_info(state->log, "port_event: del %d:%d",
addr->client, addr->port);
state->port_info(state->port_info_data, addr, NULL);
break;
default:
spa_log_info(state->log, "unhandled event %d: %d:%d",
type, addr->client, addr->port);
break;
}
}
}
int spa_alsa_seq_open(struct seq_state *state)
{
int n, i, res;
snd_seq_port_subscribe_t *sub;
snd_seq_addr_t addr;
snd_seq_queue_timer_t *timer;
snd_seq_client_pool_t *pool;
struct seq_conn reserve[16];
size_t pool_size;
if (state->opened)
return 0;
init_stream(state, SPA_DIRECTION_INPUT);
init_stream(state, SPA_DIRECTION_OUTPUT);
spa_zero(reserve);
for (i = 0; i < 16; i++) {
spa_log_debug(state->log, "open %d", i);
if ((res = seq_open(state, &reserve[i], false, (i == 0))) < 0)
break;
}
if (i >= 2) {
state->event = reserve[--i];
state->sys = reserve[--i];
res = 0;
}
for (n = --i; n >= 0; n--) {
spa_log_debug(state->log, "close %d", n);
seq_close(state, &reserve[n]);
}
if (res < 0) {
spa_log_error(state->log, "open failed: %s", snd_strerror(res));
return res;
}
if ((res = seq_init(state, &state->sys, false)) < 0)
goto error_close;
snd_seq_set_client_name(state->sys.hndl, "PipeWire-System");
if ((res = seq_init(state, &state->event, true)) < 0)
goto error_close;
snd_seq_set_client_name(state->event.hndl, "PipeWire-RT-Event");
/* connect to system announce */
snd_seq_port_subscribe_alloca(&sub);
addr.client = SND_SEQ_CLIENT_SYSTEM;
addr.port = SND_SEQ_PORT_SYSTEM_ANNOUNCE;
snd_seq_port_subscribe_set_sender(sub, &addr);
snd_seq_port_subscribe_set_dest(sub, &state->sys.addr);
if ((res = snd_seq_subscribe_port(state->sys.hndl, sub)) < 0) {
spa_log_warn(state->log, "failed to connect announce port: %s", snd_strerror(res));
}
addr.client = SND_SEQ_CLIENT_SYSTEM;
addr.port = SND_SEQ_PORT_SYSTEM_TIMER;
snd_seq_port_subscribe_set_sender(sub, &addr);
if ((res = snd_seq_subscribe_port(state->sys.hndl, sub)) < 0) {
spa_log_warn(state->log, "failed to connect timer port: %s", snd_strerror(res));
}
state->sys.source.func = alsa_seq_on_sys;
state->sys.source.data = state;
spa_loop_add_source(state->main_loop, &state->sys.source);
/* increase event queue timer resolution */
snd_seq_queue_timer_alloca(&timer);
if ((res = snd_seq_get_queue_timer(state->event.hndl, state->event.queue_id, timer)) < 0) {
spa_log_warn(state->log, "failed to get queue timer: %s", snd_strerror(res));
}
snd_seq_queue_timer_set_resolution(timer, INT_MAX);
if ((res = snd_seq_set_queue_timer(state->event.hndl, state->event.queue_id, timer)) < 0) {
spa_log_warn(state->log, "failed to set queue timer: %s", snd_strerror(res));
}
/* Increase client pool sizes. This determines the max sysex message that
* can be received. */
snd_seq_client_pool_alloca(&pool);
if ((res = snd_seq_get_client_pool(state->event.hndl, pool)) < 0) {
spa_log_warn(state->log, "failed to get pool: %s", snd_strerror(res));
} else {
/* make sure we at least use the default size */
pool_size = snd_seq_client_pool_get_output_pool(pool);
pool_size = SPA_MAX(pool_size, snd_seq_client_pool_get_input_pool(pool));
/* The pool size is in cells, which are about 24 bytes long. Try to
* make sure we can fit sysex of at least twice the quantum limit. */
pool_size = SPA_MAX(pool_size, state->quantum_limit * 2 / 24);
/* The kernel ignores values larger than 2000 (by default) so clamp
* this here. It's configurable in case the kernel was modified. */
pool_size = SPA_CLAMP(pool_size, state->min_pool_size, state->max_pool_size);
snd_seq_client_pool_set_input_pool(pool, pool_size);
snd_seq_client_pool_set_output_pool(pool, pool_size);
if ((res = snd_seq_set_client_pool(state->event.hndl, pool)) < 0) {
spa_log_warn(state->log, "failed to set pool: %s", snd_strerror(res));
}
}
init_ports(state);
if ((res = spa_system_timerfd_create(state->data_system,
CLOCK_MONOTONIC, SPA_FD_CLOEXEC | SPA_FD_NONBLOCK)) < 0)
goto error_close;
state->timerfd = res;
state->opened = true;
return 0;
error_close:
seq_close(state, &state->event);
seq_close(state, &state->sys);
return res;
}
int spa_alsa_seq_close(struct seq_state *state)
{
int res = 0;
if (!state->opened)
return 0;
spa_loop_remove_source(state->main_loop, &state->sys.source);
seq_close(state, &state->sys);
seq_close(state, &state->event);
uninit_stream(state, SPA_DIRECTION_INPUT);
uninit_stream(state, SPA_DIRECTION_OUTPUT);
spa_system_close(state->data_system, state->timerfd);
state->opened = false;
return res;
}
static int set_timeout(struct seq_state *state, uint64_t time)
{
struct itimerspec ts;
ts.it_value.tv_sec = time / SPA_NSEC_PER_SEC;
ts.it_value.tv_nsec = time % SPA_NSEC_PER_SEC;
ts.it_interval.tv_sec = 0;
ts.it_interval.tv_nsec = 0;
spa_system_timerfd_settime(state->data_system,
state->timerfd, SPA_FD_TIMER_ABSTIME, &ts, NULL);
return 0;
}
static struct seq_port *find_port(struct seq_state *state,
struct seq_stream *stream, const snd_seq_addr_t *addr)
{
uint32_t i;
for (i = 0; i < stream->last_port; i++) {
struct seq_port *port = &stream->ports[i];
if (port->valid &&
port->addr.client == addr->client &&
port->addr.port == addr->port)
return port;
}
return NULL;
}
int spa_alsa_seq_activate_port(struct seq_state *state, struct seq_port *port, bool active)
{
int res;
snd_seq_port_subscribe_t* sub;
spa_log_debug(state->log, "activate: %d.%d: started:%d active:%d wanted:%d",
port->addr.client, port->addr.port, state->started, port->active, active);
if (active && !state->started)
return 0;
if (port->active == active)
return 0;
snd_seq_port_subscribe_alloca(&sub);
if (port->direction == SPA_DIRECTION_OUTPUT) {
snd_seq_port_subscribe_set_sender(sub, &port->addr);
snd_seq_port_subscribe_set_dest(sub, &state->event.addr);
} else {
snd_seq_port_subscribe_set_sender(sub, &state->event.addr);
snd_seq_port_subscribe_set_dest(sub, &port->addr);
}
if (active) {
snd_seq_port_subscribe_set_time_update(sub, 1);
snd_seq_port_subscribe_set_time_real(sub, 1);
snd_seq_port_subscribe_set_queue(sub, state->event.queue_id);
if ((res = snd_seq_subscribe_port(state->event.hndl, sub)) < 0) {
spa_log_error(state->log, "can't subscribe to %d:%d - %s",
port->addr.client, port->addr.port, snd_strerror(res));
active = false;
}
spa_log_info(state->log, "subscribe: %s port %d.%d",
port->direction == SPA_DIRECTION_OUTPUT ? "output" : "input",
port->addr.client, port->addr.port);
} else {
if ((res = snd_seq_unsubscribe_port(state->event.hndl, sub)) < 0) {
spa_log_warn(state->log, "can't unsubscribe from %d:%d - %s",
port->addr.client, port->addr.port, snd_strerror(res));
}
spa_log_info(state->log, "unsubscribe: %s port %d.%d",
port->direction == SPA_DIRECTION_OUTPUT ? "output" : "input",
port->addr.client, port->addr.port);
}
port->active = active;
return res;
}
static struct buffer *peek_buffer(struct seq_state *state,
struct seq_port *port)
{
if (spa_list_is_empty(&port->free))
return NULL;
return spa_list_first(&port->free, struct buffer, link);
}
int spa_alsa_seq_recycle_buffer(struct seq_state *state, struct seq_port *port, uint32_t buffer_id)
{
struct buffer *b = &port->buffers[buffer_id];
if (SPA_FLAG_IS_SET(b->flags, BUFFER_FLAG_OUT)) {
spa_log_trace_fp(state->log, "%p: recycle buffer port:%p buffer-id:%u",
state, port, buffer_id);
spa_list_append(&port->free, &b->link);
SPA_FLAG_CLEAR(b->flags, BUFFER_FLAG_OUT);
}
return 0;
}
static int prepare_buffer(struct seq_state *state, struct seq_port *port)
{
if (port->buffer != NULL)
return 0;
if ((port->buffer = peek_buffer(state, port)) == NULL)
return -EPIPE;
spa_pod_builder_init(&port->builder,
port->buffer->buf->datas[0].data,
port->buffer->buf->datas[0].maxsize);
spa_pod_builder_push_sequence(&port->builder, &port->frame, 0);
return 0;
}
static int process_recycle(struct seq_state *state)
{
struct seq_stream *stream = &state->streams[SPA_DIRECTION_OUTPUT];
uint32_t i;
for (i = 0; i < stream->last_port; i++) {
struct seq_port *port = &stream->ports[i];
struct spa_io_buffers *io = port->io;
if (!port->valid || io == NULL)
continue;
if (io->status != SPA_STATUS_HAVE_DATA &&
io->buffer_id < port->n_buffers) {
spa_alsa_seq_recycle_buffer(state, port, io->buffer_id);
io->buffer_id = SPA_ID_INVALID;
}
}
return 0;
}
#define NSEC_TO_CLOCK(r,n) (((n) * (r)->denom) / ((r)->num * SPA_NSEC_PER_SEC))
#define NSEC_FROM_CLOCK(r,n) (((n) * (r)->num * SPA_NSEC_PER_SEC) / (r)->denom)
static int process_read(struct seq_state *state)
{
struct seq_stream *stream = &state->streams[SPA_DIRECTION_OUTPUT];
const bool ump = state->ump;
uint32_t i;
uint32_t *data;
uint8_t midi1_data[MAX_EVENT_SIZE];
uint32_t ump_data[MAX_EVENT_SIZE];
long size;
int res = -1;
/* copy all new midi events into their port buffers */
while (1) {
const snd_seq_addr_t *addr;
struct seq_port *port;
uint64_t ev_time, diff;
uint32_t offset;
void *event;
uint8_t *midi1_ptr;
size_t midi1_size = 0;
uint64_t ump_state = 0;
snd_seq_event_type_t SPA_UNUSED type;
if (ump) {
#ifdef HAVE_ALSA_UMP
snd_seq_ump_event_t *ev;
res = snd_seq_ump_event_input(state->event.hndl, &ev);
if (res <= 0)
break;
debug_ump_event(state, ev);
event = ev;
addr = &ev->source;
ev_time = SPA_TIMESPEC_TO_NSEC(&ev->time.time);
type = ev->type;
#else
spa_assert_not_reached();
#endif
} else {
snd_seq_event_t *ev;
res = snd_seq_event_input(state->event.hndl, &ev);
if (res <= 0)
break;
debug_event(state, ev);
event = ev;
addr = &ev->source;
ev_time = SPA_TIMESPEC_TO_NSEC(&ev->time.time);
type = ev->type;
}
if ((port = find_port(state, stream, addr)) == NULL) {
spa_log_debug(state->log, "unknown port %d.%d",
addr->client, addr->port);
continue;
}
if (port->io == NULL || port->n_buffers == 0)
continue;
if ((res = prepare_buffer(state, port)) < 0) {
spa_log_debug(state->log, "can't prepare buffer port:%p %d.%d: %s",
port, addr->client, addr->port, spa_strerror(res));
continue;
}
/* queue_time is the estimated current time of the queue as calculated by
* the DLL. Calculate the age of the event. */
if (state->queue_time > ev_time)
diff = state->queue_time - ev_time;
else
diff = 0;
/* convert the age to samples and convert to an offset */
offset = NSEC_TO_CLOCK(&state->rate, diff);
if (state->duration > offset)
offset = state->duration - 1 - offset;
else
offset = 0;
if (ump) {
#ifdef HAVE_ALSA_UMP
snd_seq_ump_event_t *ev = event;
data = (uint32_t*)&ev->ump[0];
size = spa_ump_message_size(snd_ump_msg_hdr_type(ev->ump[0])) * 4;
#else
spa_assert_not_reached();
#endif
} else {
snd_seq_event_t *ev = event;
snd_midi_event_reset_decode(stream->codec);
if ((size = snd_midi_event_decode(stream->codec, midi1_data, sizeof(midi1_data), ev)) < 0) {
spa_log_warn(state->log, "decode failed: %s", snd_strerror(size));
continue;
}
midi1_ptr = midi1_data;
midi1_size = size;
}
do {
if (!ump) {
data = ump_data;
size = spa_ump_from_midi(&midi1_ptr, &midi1_size,
ump_data, sizeof(ump_data), 0, &ump_state);
if (size <= 0)
break;
}
spa_log_trace_fp(state->log, "event %d time:%"PRIu64" offset:%d size:%ld port:%d.%d",
type, ev_time, offset, size, addr->client, addr->port);
spa_pod_builder_control(&port->builder, offset, SPA_CONTROL_UMP);
spa_pod_builder_bytes(&port->builder, data, size);
/* make sure we can fit at least one control event of max size otherwise
* we keep the event in the queue and try to copy it in the next cycle */
if (port->builder.state.offset +
sizeof(struct spa_pod_control) +
MAX_EVENT_SIZE > port->buffer->buf->datas[0].maxsize)
goto done;
} while (!ump);
}
done:
if (res < 0 && res != -EAGAIN)
spa_log_warn(state->log, "event read failed: %s", snd_strerror(res));
/* prepare a buffer on each port, some ports might have their
* buffer filled above */
res = 0;
for (i = 0; i < stream->last_port; i++) {
struct seq_port *port = &stream->ports[i];
struct spa_io_buffers *io = port->io;
if (!port->valid || io == NULL)
continue;
if (prepare_buffer(state, port) >= 0) {
spa_pod_builder_pop(&port->builder, &port->frame);
port->buffer->buf->datas[0].chunk->offset = 0;
port->buffer->buf->datas[0].chunk->size = port->builder.state.offset;
if (port->builder.state.offset > port->buffer->buf->datas[0].maxsize) {
spa_log_warn(state->log, "control overflow: %d > %d",
port->builder.state.offset,
port->buffer->buf->datas[0].maxsize);
}
/* move buffer to ready queue */
spa_list_remove(&port->buffer->link);
SPA_FLAG_SET(port->buffer->flags, BUFFER_FLAG_OUT);
spa_list_append(&port->ready, &port->buffer->link);
port->buffer = NULL;
}
/* if there is already data, continue */
if (io->status == SPA_STATUS_HAVE_DATA) {
res |= SPA_STATUS_HAVE_DATA;
continue;
}
if (io->buffer_id < port->n_buffers)
spa_alsa_seq_recycle_buffer(state, port, io->buffer_id);
if (spa_list_is_empty(&port->ready)) {
/* we have no ready buffers */
io->buffer_id = SPA_ID_INVALID;
io->status = -EPIPE;
} else {
struct buffer *b = spa_list_first(&port->ready, struct buffer, link);
spa_list_remove(&b->link);
/* dequeue ready buffer */
io->buffer_id = b->id;
io->status = SPA_STATUS_HAVE_DATA;
res |= SPA_STATUS_HAVE_DATA;
}
}
return res;
}
static int process_write(struct seq_state *state)
{
struct seq_stream *stream = &state->streams[SPA_DIRECTION_INPUT];
const bool ump = state->ump;
uint32_t i;
int err, res = 0;
for (i = 0; i < stream->last_port; i++) {
struct seq_port *port = &stream->ports[i];
struct spa_io_buffers *io = port->io;
struct buffer *buffer;
struct spa_pod_sequence *pod;
struct spa_data *d;
struct spa_pod_control *c;
uint64_t out_time;
snd_seq_real_time_t out_rt;
if (!port->valid || io == NULL)
continue;
if (io->status != SPA_STATUS_HAVE_DATA ||
io->buffer_id >= port->n_buffers)
continue;
buffer = &port->buffers[io->buffer_id];
d = &buffer->buf->datas[0];
io->status = SPA_STATUS_NEED_DATA;
spa_node_call_reuse_buffer(&state->callbacks, i, io->buffer_id);
res |= SPA_STATUS_NEED_DATA;
pod = spa_pod_from_data(d->data, d->maxsize, d->chunk->offset, d->chunk->size);
if (pod == NULL) {
spa_log_warn(state->log, "invalid sequence in buffer max:%u offset:%u size:%u",
d->maxsize, d->chunk->offset, d->chunk->size);
continue;
}
SPA_POD_SEQUENCE_FOREACH(pod, c) {
size_t body_size;
uint8_t *body;
if (c->type != SPA_CONTROL_UMP)
continue;
body = SPA_POD_BODY(&c->value);
body_size = SPA_POD_BODY_SIZE(&c->value);
out_time = state->queue_time + NSEC_FROM_CLOCK(&state->rate, c->offset);
out_rt.tv_nsec = out_time % SPA_NSEC_PER_SEC;
out_rt.tv_sec = out_time / SPA_NSEC_PER_SEC;
spa_log_trace_fp(state->log, "event time:%"PRIu64" offset:%d size:%zd port:%d.%d",
out_time, c->offset, body_size, port->addr.client, port->addr.port);
if (ump) {
#ifdef HAVE_ALSA_UMP
snd_seq_ump_event_t ev;
snd_seq_ump_ev_clear(&ev);
snd_seq_ev_set_ump_data(&ev, body, SPA_MIN(sizeof(ev.ump), (size_t)body_size));
snd_seq_ev_set_source(&ev, state->event.addr.port);
snd_seq_ev_set_dest(&ev, port->addr.client, port->addr.port);
snd_seq_ev_schedule_real(&ev, state->event.queue_id, 0, &out_rt);
if ((err = snd_seq_ump_event_output(state->event.hndl, &ev)) < 0) {
spa_log_warn(state->log, "failed to output event: %s",
snd_strerror(err));
}
#else
spa_assert_not_reached();
#endif
} else {
snd_seq_event_t ev;
uint8_t data[MAX_EVENT_SIZE];
int size;
if ((size = spa_ump_to_midi((uint32_t *)body, body_size, data, sizeof(data))) <= 0)
continue;
snd_seq_ev_clear(&ev);
snd_midi_event_reset_encode(stream->codec);
if ((size = snd_midi_event_encode(stream->codec, data, size, &ev)) <= 0) {
spa_log_warn(state->log, "failed to encode event: %s", snd_strerror(size));
continue;
}
snd_seq_ev_set_source(&ev, state->event.addr.port);
snd_seq_ev_set_dest(&ev, port->addr.client, port->addr.port);
snd_seq_ev_schedule_real(&ev, state->event.queue_id, 0, &out_rt);
if ((err = snd_seq_event_output(state->event.hndl, &ev)) < 0) {
spa_log_warn(state->log, "failed to output event: %s",
snd_strerror(err));
}
}
}
}
snd_seq_drain_output(state->event.hndl);
return res;
}
static void update_position(struct seq_state *state)
{
if (SPA_LIKELY(state->position)) {
struct spa_io_clock *clock = &state->position->clock;
state->rate = clock->rate;
if (state->rate.num == 0 || state->rate.denom == 0)
state->rate = SPA_FRACTION(1, 48000);
state->duration = clock->duration;
} else {
state->rate = SPA_FRACTION(1, 48000);
state->duration = 1024;
}
state->threshold = state->duration;
}
static int update_time(struct seq_state *state, uint64_t nsec, bool follower)
{
snd_seq_queue_status_t *status;
const snd_seq_real_time_t* queue_time;
uint64_t queue_real;
double err, corr;
uint64_t q1, q2;
/* take queue time */
snd_seq_queue_status_alloca(&status);
snd_seq_get_queue_status(state->event.hndl, state->event.queue_id, status);
queue_time = snd_seq_queue_status_get_real_time(status);
queue_real = SPA_TIMESPEC_TO_NSEC(queue_time);
if (state->dll.bw == 0.0) {
spa_dll_set_bw(&state->dll, SPA_DLL_BW_MAX, state->threshold,
state->rate.denom);
state->next_time = nsec;
state->base_time = nsec;
state->queue_next = queue_real;
}
/* track our estimated elapsed time against the real elapsed queue time */
q1 = NSEC_TO_CLOCK(&state->rate, state->queue_next);
q2 = NSEC_TO_CLOCK(&state->rate, queue_real);
err = ((int64_t)q1 - (int64_t) q2);
if (fabs(err) > state->threshold)
spa_dll_init(&state->dll);
err = SPA_CLAMP(err, -64, 64);
corr = spa_dll_update(&state->dll, err);
/* this is our current estimated queue time and rate */
state->queue_time = state->queue_next;
state->queue_corr = corr;
/* make a new estimated queue time with the current quantum, if we are following,
* use the rate correction, else we will use the rate correction only for the new
* timeout. */
if (state->following)
state->queue_next += (uint64_t)(state->threshold * corr * 1e9 / state->rate.denom);
else
state->queue_next += (uint64_t)(state->threshold * 1e9 / state->rate.denom);
if ((state->next_time - state->base_time) > BW_PERIOD) {
state->base_time = state->next_time;
spa_log_debug(state->log, "%p: follower:%d rate:%f bw:%f err:%f (%f %f %f)",
state, follower, corr, state->dll.bw, err,
state->dll.z1, state->dll.z2, state->dll.z3);
}
state->next_time += (uint64_t)(state->threshold / corr * 1e9 / state->rate.denom);
if (SPA_LIKELY(state->clock)) {
state->clock->nsec = nsec;
state->clock->rate = state->rate;
state->clock->position += state->clock->duration;
state->clock->duration = state->duration;
state->clock->delay = (int64_t)(state->duration * corr);
state->clock->rate_diff = corr;
state->clock->next_nsec = state->next_time;
}
spa_log_trace_fp(state->log, "now:%"PRIu64" queue:%"PRIu64" err:%f corr:%f next:%"PRIu64" thr:%d",
nsec, queue_real, err, corr, state->next_time, state->threshold);
return 0;
}
int spa_alsa_seq_process(struct seq_state *state)
{
int res;
update_position(state);
res = process_recycle(state);
if (state->following && state->position) {
update_time(state, state->position->clock.nsec, true);
res |= process_read(state);
}
res |= process_write(state);
return res;
}
static void alsa_on_timeout_event(struct spa_source *source)
{
struct seq_state *state = source->data;
uint64_t expire;
int res;
if (state->started) {
if ((res = spa_system_timerfd_read(state->data_system, state->timerfd, &expire)) < 0) {
if (res != -EAGAIN)
spa_log_warn(state->log, "%p: error reading timerfd: %s",
state, spa_strerror(res));
return;
}
}
state->current_time = state->next_time;
spa_log_trace(state->log, "timeout %"PRIu64, state->current_time);
if (SPA_LIKELY(state->position)) {
struct spa_io_clock *clock = &state->position->clock;
state->rate = clock->target_rate;
if (state->rate.num == 0 || state->rate.denom == 0)
state->rate = SPA_FRACTION(1, 48000);
state->duration = clock->target_duration;
} else {
state->rate = SPA_FRACTION(1, 48000);
state->duration = 1024;
}
state->threshold = state->duration;
update_time(state, state->current_time, false);
res = process_read(state);
if (res >= 0)
spa_node_call_ready(&state->callbacks, res | SPA_STATUS_NEED_DATA);
set_timeout(state, state->next_time);
}
static void reset_buffers(struct seq_state *this, struct seq_port *port)
{
uint32_t i;
spa_list_init(&port->free);
spa_list_init(&port->ready);
for (i = 0; i < port->n_buffers; i++) {
struct buffer *b = &port->buffers[i];
if (port->direction == SPA_DIRECTION_INPUT) {
SPA_FLAG_SET(b->flags, BUFFER_FLAG_OUT);
} else {
spa_list_append(&port->free, &b->link);
SPA_FLAG_CLEAR(b->flags, BUFFER_FLAG_OUT);
}
}
}
static void reset_stream(struct seq_state *this, struct seq_stream *stream, bool active)
{
uint32_t i;
for (i = 0; i < stream->last_port; i++) {
struct seq_port *port = &stream->ports[i];
if (port->valid) {
reset_buffers(this, port);
spa_alsa_seq_activate_port(this, port, active);
}
}
}
static int set_timers(struct seq_state *state)
{
struct timespec now;
int res;
if ((res = spa_system_clock_gettime(state->data_system, CLOCK_MONOTONIC, &now)) < 0)
return res;
state->queue_time = 0;
state->queue_corr = 1.0;
spa_dll_init(&state->dll);
state->next_time = SPA_TIMESPEC_TO_NSEC(&now);
if (state->following) {
set_timeout(state, 0);
} else {
set_timeout(state, state->next_time);
}
return 0;
}
static inline bool is_following(struct seq_state *state)
{
return state->position && state->clock && state->position->clock.id != state->clock->id;
}
int spa_alsa_seq_start(struct seq_state *state)
{
int res;
if (state->started)
return 0;
state->following = is_following(state);
spa_log_debug(state->log, "alsa %p: start follower:%d", state, state->following);
if ((res = snd_seq_start_queue(state->event.hndl, state->event.queue_id, NULL)) < 0) {
spa_log_error(state->log, "failed to start queue: %s", snd_strerror(res));
return res;
}
while (snd_seq_drain_output(state->event.hndl) > 0)
sleep(1);
update_position(state);
state->started = true;
reset_stream(state, &state->streams[SPA_DIRECTION_INPUT], true);
reset_stream(state, &state->streams[SPA_DIRECTION_OUTPUT], true);
state->source.func = alsa_on_timeout_event;
state->source.data = state;
state->source.fd = state->timerfd;
state->source.mask = SPA_IO_IN;
state->source.rmask = 0;
spa_loop_add_source(state->data_loop, &state->source);
res = set_timers(state);
return res;
}
static int do_reassign_follower(struct spa_loop *loop,
bool async,
uint32_t seq,
const void *data,
size_t size,
void *user_data)
{
struct seq_state *state = user_data;
int res;
if ((res = set_timers(state)) < 0)
spa_log_error(state->log, "can't set timers: %s", spa_strerror(res));
return 0;
}
int spa_alsa_seq_reassign_follower(struct seq_state *state)
{
bool following;
if (!state->started)
return 0;
following = is_following(state);
if (following != state->following) {
spa_log_debug(state->log, "alsa %p: reassign follower %d->%d", state, state->following, following);
state->following = following;
spa_loop_invoke(state->data_loop, do_reassign_follower, 0, NULL, 0, true, state);
}
return 0;
}
static int do_remove_source(struct spa_loop *loop,
bool async,
uint32_t seq,
const void *data,
size_t size,
void *user_data)
{
struct seq_state *state = user_data;
spa_loop_remove_source(state->data_loop, &state->source);
set_timeout(state, 0);
return 0;
}
int spa_alsa_seq_pause(struct seq_state *state)
{
int res;
if (!state->started)
return 0;
spa_log_debug(state->log, "alsa %p: pause", state);
spa_loop_invoke(state->data_loop, do_remove_source, 0, NULL, 0, true, state);
if ((res = snd_seq_stop_queue(state->event.hndl, state->event.queue_id, NULL)) < 0) {
spa_log_warn(state->log, "failed to stop queue: %s", snd_strerror(res));
}
while (snd_seq_drain_output(state->event.hndl) > 0)
sleep(1);
state->started = false;
reset_stream(state, &state->streams[SPA_DIRECTION_INPUT], false);
reset_stream(state, &state->streams[SPA_DIRECTION_OUTPUT], false);
return 0;
}
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