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pipewire/pipewire-jack/src/pipewire-jack.c
Wim Taymans 3785896533 mixer: rework the control mixers to use the parser 
Using the parser for the spa_pod_sequence in the data buffers is
required in order to safely read the pods while there could be
concurrent writes.

See #4822
2025-07-29 15:33:43 +02:00

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/* PipeWire */
/* SPDX-FileCopyrightText: Copyright © 2018 Wim Taymans */
/* SPDX-FileCopyrightText: Copyright © 2024 Nedko Arnaudov */
/* SPDX-License-Identifier: MIT */
#include "config.h"
#include <stdio.h>
#include <unistd.h>
#include <sys/mman.h>
#include <regex.h>
#include <math.h>
#include <threads.h>
#include <jack/jack.h>
#include <jack/intclient.h>
#include <jack/session.h>
#include <jack/thread.h>
#include <jack/midiport.h>
#include <jack/uuid.h>
#include <jack/metadata.h>
#include <spa/support/cpu.h>
#include <spa/param/audio/format-utils.h>
#include <spa/param/video/format-utils.h>
#include <spa/param/latency-utils.h>
#include <spa/debug/types.h>
#include <spa/debug/pod.h>
#include <spa/utils/json.h>
#include <spa/utils/result.h>
#include <spa/utils/string.h>
#include <spa/utils/ringbuffer.h>
#include <spa/control/ump-utils.h>
#include <pipewire/pipewire.h>
#include <pipewire/private.h>
#include <pipewire/thread.h>
#include <pipewire/data-loop.h>
#include "pipewire/extensions/client-node.h"
#include "pipewire/extensions/metadata.h"
#include "pipewire-jack-extensions.h"
/* use 512KB stack per thread - the default is way too high to be feasible
* with mlockall() on many systems */
#define THREAD_STACK 524288
#define DEFAULT_RT_MAX RTPRIO_CLIENT
#define JACK_CLIENT_NAME_SIZE 256
#define JACK_PORT_NAME_SIZE 256
#define JACK_PORT_TYPE_SIZE 32
#define MONITOR_EXT " Monitor"
#define MAX_MIX 1024
#define MAX_CLIENT_PORTS 768
#define MAX_ALIGN 32
#define MAX_BUFFERS 2
#define MAX_BUFFER_DATAS 1u
#define REAL_JACK_PORT_NAME_SIZE (JACK_CLIENT_NAME_SIZE + JACK_PORT_NAME_SIZE)
PW_LOG_TOPIC_STATIC(jack_log_topic, "jack");
#define PW_LOG_TOPIC_DEFAULT jack_log_topic
#define TYPE_ID_AUDIO 0
#define TYPE_ID_VIDEO 1
#define TYPE_ID_MIDI 2
#define TYPE_ID_OSC 3
#define TYPE_ID_UMP 4
#define TYPE_ID_OTHER 5
#define TYPE_ID_IS_EVENT(t) ((t) >= TYPE_ID_MIDI && (t) <= TYPE_ID_UMP)
#define TYPE_ID_CAN_OSC(t) ((t) == TYPE_ID_MIDI || (t) == TYPE_ID_OSC)
#define TYPE_ID_IS_HIDDEN(t) ((t) >= TYPE_ID_OTHER)
#define TYPE_ID_IS_COMPATIBLE(a,b)(((a) == (b)) || (TYPE_ID_IS_EVENT(a) && TYPE_ID_IS_EVENT(b)))
#define SELF_CONNECT_ALLOW 0
#define SELF_CONNECT_FAIL_EXT -1
#define SELF_CONNECT_IGNORE_EXT 1
#define SELF_CONNECT_FAIL_ALL -2
#define SELF_CONNECT_IGNORE_ALL 2
#define OTHER_CONNECT_ALLOW 1
#define OTHER_CONNECT_FAIL -1
#define OTHER_CONNECT_IGNORE 0
#define NOTIFY_BUFFER_SIZE (1u<<13)
#define NOTIFY_BUFFER_MASK (NOTIFY_BUFFER_SIZE-1)
struct notify {
#define NOTIFY_ACTIVE_FLAG (1<<0)
#define NOTIFY_TYPE_NONE ((0<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_REGISTRATION ((1<<4))
#define NOTIFY_TYPE_PORTREGISTRATION ((2<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_CONNECT ((3<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_BUFFER_FRAMES ((4<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_SAMPLE_RATE ((5<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_FREEWHEEL ((6<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_SHUTDOWN ((7<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_LATENCY ((8<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_TOTAL_LATENCY ((9<<4)|NOTIFY_ACTIVE_FLAG)
#define NOTIFY_TYPE_PORT_RENAME ((10<<4)|NOTIFY_ACTIVE_FLAG)
int type;
struct object *object;
int arg1;
const char *msg;
};
struct client;
struct port;
struct globals {
jack_thread_creator_t creator;
pthread_mutex_t lock;
struct pw_array descriptions;
struct spa_list free_objects;
struct spa_thread_utils *thread_utils;
uint32_t max_frames;
};
static struct globals globals;
static bool mlock_warned = false;
#define MIDI_SCRATCH_FRAMES 8192
static thread_local float midi_scratch[MIDI_SCRATCH_FRAMES];
#define OBJECT_CHUNK 8
#define RECYCLE_THRESHOLD 128
typedef void (*mix_func) (float *dst, float *src[], uint32_t n_src, bool aligned, uint32_t n_samples);
struct object {
struct spa_list link;
struct client *client;
#define INTERFACE_Invalid 0
#define INTERFACE_Port 1
#define INTERFACE_Node 2
#define INTERFACE_Link 3
#define INTERFACE_Client 4
uint32_t type;
uint32_t id;
uint32_t serial;
union {
struct {
char name[1024];
int32_t pid;
} pwclient;
struct {
char name[JACK_CLIENT_NAME_SIZE+1];
char node_name[512];
int32_t priority;
uint32_t client_id;
unsigned is_jack:1;
unsigned is_running:1;
} node;
struct {
uint32_t src;
uint32_t dst;
uint32_t src_serial;
uint32_t dst_serial;
bool src_ours;
bool dst_ours;
struct port *our_input;
struct port *our_output;
} port_link;
struct {
unsigned long flags;
char old_name[REAL_JACK_PORT_NAME_SIZE+1];
char name[REAL_JACK_PORT_NAME_SIZE+1];
char alias1[REAL_JACK_PORT_NAME_SIZE+1];
char alias2[REAL_JACK_PORT_NAME_SIZE+1];
char system[REAL_JACK_PORT_NAME_SIZE+1];
uint32_t system_id;
uint32_t type_id;
uint32_t node_id;
uint32_t monitor_requests;
int32_t priority;
struct port *port;
bool is_monitor;
struct object *node;
struct spa_latency_info latency[2];
} port;
};
struct pw_proxy *proxy;
struct spa_hook proxy_listener;
struct spa_hook object_listener;
int registered;
unsigned int visible;
unsigned int removing:1;
unsigned int removed:1;
unsigned int to_free:1;
};
struct midi_buffer {
#define MIDI_BUFFER_MAGIC 0x900df00d
uint32_t magic;
int32_t buffer_size;
uint32_t nframes;
int32_t write_pos;
uint32_t event_count;
uint32_t lost_events;
};
#define MIDI_INLINE_MAX 4
struct midi_event {
uint16_t time;
uint16_t size;
union {
uint32_t byte_offset;
uint8_t inline_data[MIDI_INLINE_MAX];
};
};
struct buffer {
struct spa_list link;
#define BUFFER_FLAG_OUT (1<<0)
#define BUFFER_FLAG_MAPPED (1<<1)
uint32_t flags;
uint32_t id;
struct spa_data datas[MAX_BUFFER_DATAS];
uint32_t n_datas;
struct pw_memmap *mem[MAX_BUFFER_DATAS+1];
uint32_t n_mem;
};
struct mix_info {
struct spa_pod_parser parser;
struct spa_pod_frame frame;
struct spa_pod_control control;
const void *control_body;
};
struct mix {
struct spa_list link;
struct spa_list port_link;
uint32_t id;
uint32_t peer_id;
struct port *port;
struct port *peer_port;
struct spa_io_buffers *io[2];
struct spa_list queue;
struct buffer buffers[MAX_BUFFERS];
uint32_t n_buffers;
struct mix_info mix_info;
unsigned int to_free:1;
};
struct port {
bool valid;
struct spa_list link;
struct client *client;
enum spa_direction direction;
uint32_t port_id;
struct object *object;
struct pw_properties *props;
struct spa_port_info info;
#define IDX_EnumFormat 0
#define IDX_Buffers 1
#define IDX_IO 2
#define IDX_Format 3
#define IDX_Latency 4
#define N_PORT_PARAMS 5
struct spa_param_info params[N_PORT_PARAMS];
struct spa_io_buffers io[2];
struct spa_list mix;
uint32_t n_mix;
struct mix *global_mix;
struct port *tied;
unsigned int empty_out:1;
unsigned int zeroed:1;
unsigned int to_free:1;
void *(*get_buffer) (struct port *p, jack_nframes_t frames);
float *emptyptr;
float empty[];
};
struct link {
struct spa_list link;
struct spa_list target_link;
struct client *client;
uint32_t node_id;
struct pw_memmap *mem;
struct pw_node_activation *activation;
int signalfd;
void (*trigger) (struct link *l, uint64_t nsec);
};
struct context {
struct pw_loop *l;
struct pw_thread_loop *loop; /* thread_lock protects all below */
struct pw_context *context;
struct pw_loop *nl;
struct pw_thread_loop *notify;
struct spa_thread_utils *old_thread_utils;
struct spa_thread_utils thread_utils;
pthread_mutex_t lock; /* protects map and lists below, in addition to thread_lock */
struct spa_list objects;
uint32_t free_count;
};
#define GET_DIRECTION(f) ((f) & JackPortIsInput ? SPA_DIRECTION_INPUT : SPA_DIRECTION_OUTPUT)
#define GET_PORT(c,d,p) (pw_map_lookup(&c->ports[d], p))
struct metadata {
struct pw_metadata *proxy;
struct spa_hook proxy_listener;
struct spa_hook listener;
char default_audio_sink[1024];
char default_audio_source[1024];
};
struct frame_times {
uint64_t frames;
uint64_t nsec;
uint64_t next_nsec;
uint32_t buffer_frames;
uint32_t sample_rate;
double rate_diff;
};
struct client {
char name[JACK_CLIENT_NAME_SIZE+1];
struct context context;
char *server_name;
char *load_name; /* load module name */
char *load_init; /* initialization string */
jack_uuid_t session_id; /* requested session_id */
struct pw_loop *l;
struct pw_data_loop *loop;
struct pw_properties *props;
struct pw_core *core;
struct spa_hook core_listener;
struct pw_mempool *pool;
int pending_sync;
int last_sync;
int last_res;
struct spa_node_info info;
struct pw_registry *registry;
struct spa_hook registry_listener;
struct pw_client_node *node;
struct spa_hook node_listener;
struct spa_hook proxy_listener;
struct metadata *metadata;
struct metadata *settings;
uint32_t node_id;
uint32_t serial;
struct object *object;
struct spa_source *socket_source;
struct spa_source *notify_source;
void *notify_buffer;
struct spa_ringbuffer notify_ring;
JackThreadCallback thread_callback;
void *thread_arg;
JackThreadInitCallback thread_init_callback;
void *thread_init_arg;
JackShutdownCallback shutdown_callback;
void *shutdown_arg;
JackInfoShutdownCallback info_shutdown_callback;
void *info_shutdown_arg;
JackProcessCallback process_callback;
void *process_arg;
JackFreewheelCallback freewheel_callback;
void *freewheel_arg;
JackBufferSizeCallback bufsize_callback;
void *bufsize_arg;
JackSampleRateCallback srate_callback;
void *srate_arg;
JackClientRegistrationCallback registration_callback;
void *registration_arg;
JackPortRegistrationCallback portregistration_callback;
void *portregistration_arg;
JackPortConnectCallback connect_callback;
void *connect_arg;
JackPortRenameCallback rename_callback;
void *rename_arg;
JackGraphOrderCallback graph_callback;
void *graph_arg;
JackXRunCallback xrun_callback;
void *xrun_arg;
JackLatencyCallback latency_callback;
void *latency_arg;
JackSyncCallback sync_callback;
void *sync_arg;
JackTimebaseCallback timebase_callback;
void *timebase_arg;
JackPropertyChangeCallback property_callback;
void *property_arg;
struct spa_io_position *position;
uint32_t sample_rate;
uint32_t buffer_frames;
struct spa_fraction latency;
struct spa_list mix;
struct spa_list free_mix;
struct spa_list free_ports;
struct pw_map ports[2];
uint32_t n_ports;
struct spa_list links;
uint32_t driver_id;
struct pw_node_activation *driver_activation;
struct pw_memmap *mem;
struct pw_node_activation *activation;
uint32_t xrun_count;
struct {
struct spa_io_position *position;
struct pw_node_activation *driver_activation;
struct spa_list target_links;
unsigned int prepared:1;
unsigned int first:1;
unsigned int thread_entered:1;
} rt;
pthread_mutex_t rt_lock;
unsigned int rt_locked:1;
unsigned int data_locked:1;
unsigned int started:1;
unsigned int active:1;
unsigned int destroyed:1;
unsigned int has_transport:1;
unsigned int allow_mlock:1;
unsigned int warn_mlock:1;
unsigned int timeowner_conditional:1;
unsigned int show_monitor:1;
unsigned int show_midi:1;
unsigned int merge_monitor:1;
unsigned int short_name:1;
unsigned int filter_name:1;
unsigned int freewheeling:1;
unsigned int locked_process:1;
unsigned int default_as_system:1;
int self_connect_mode;
int other_connect_mode;
int rt_max;
unsigned int fix_midi_events:1;
unsigned int global_buffer_size:1;
unsigned int global_sample_rate:1;
unsigned int passive_links:1;
unsigned int pending_callbacks:1;
int frozen_callbacks;
char filter_char;
uint32_t max_ports;
unsigned int fill_aliases:1;
unsigned int writable_input:1;
unsigned int async:1;
unsigned int flag_midi2:1;
uint32_t max_frames;
uint32_t max_align;
mix_func mix_function;
jack_position_t jack_position;
jack_transport_state_t jack_state;
struct frame_times jack_times;
};
#define return_val_if_fail(expr, val) \
({ \
if (SPA_UNLIKELY(!(expr))) { \
pw_log_warn("'%s' failed at %s:%u %s()", \
#expr , __FILE__, __LINE__, __func__); \
return (val); \
} \
})
#define return_if_fail(expr) \
({ \
if (SPA_UNLIKELY(!(expr))) { \
pw_log_warn("'%s' failed at %s:%u %s()", \
#expr , __FILE__, __LINE__, __func__); \
return; \
} \
})
static int do_sync(struct client *client);
static struct object *find_by_serial(struct client *c, uint32_t serial);
#include "metadata.c"
int pw_jack_match_rules(const char *rules, size_t size, const struct spa_dict *props,
int (*matched) (void *data, const char *action, const char *val, int len),
void *data);
static struct object * alloc_object(struct client *c, int type)
{
struct object *o;
int i;
pthread_mutex_lock(&globals.lock);
if (spa_list_is_empty(&globals.free_objects)) {
o = calloc(OBJECT_CHUNK, sizeof(struct object));
if (o == NULL) {
pthread_mutex_unlock(&globals.lock);
return NULL;
}
o[0].to_free = true;
for (i = 0; i < OBJECT_CHUNK; i++)
spa_list_append(&globals.free_objects, &o[i].link);
}
o = spa_list_first(&globals.free_objects, struct object, link);
spa_list_remove(&o->link);
pthread_mutex_unlock(&globals.lock);
o->client = c;
o->removed = false;
o->type = type;
pw_log_debug("%p: object:%p type:%d", c, o, type);
return o;
}
static void recycle_objects(struct client *c, uint32_t remain)
{
struct object *o, *t;
pthread_mutex_lock(&globals.lock);
spa_list_for_each_safe(o, t, &c->context.objects, link) {
pw_log_debug("%p: recycle object:%p remived:%d type:%d id:%u/%u %u/%u",
c, o, o->removed, o->type, o->id, o->serial,
c->context.free_count, remain);
if (o->removed) {
spa_list_remove(&o->link);
memset(o, 0, sizeof(struct object));
spa_list_append(&globals.free_objects, &o->link);
if (--c->context.free_count == remain)
break;
}
}
pthread_mutex_unlock(&globals.lock);
}
/* JACK clients expect the objects to hang around after
* they are unregistered and freed. We mark the object removed and
* move it to the end of the queue. */
static void free_object(struct client *c, struct object *o)
{
pw_log_debug("%p: object:%p type:%d %u/%u", c, o, o->type,
c->context.free_count, RECYCLE_THRESHOLD);
pthread_mutex_lock(&c->context.lock);
spa_list_remove(&o->link);
o->removed = true;
o->id = SPA_ID_INVALID;
spa_list_append(&c->context.objects, &o->link);
if (++c->context.free_count >= RECYCLE_THRESHOLD)
recycle_objects(c, RECYCLE_THRESHOLD / 2);
pthread_mutex_unlock(&c->context.lock);
}
static inline struct object *port_to_object(const jack_port_t *port)
{
return (struct object*)port;
}
static inline jack_port_t *object_to_port(struct object *o)
{
return (jack_port_t*)o;
}
struct io_info {
struct mix *mix;
void *data;
size_t size;
};
static int
do_mix_set_io(struct spa_loop *loop, bool async, uint32_t seq,
const void *data, size_t size, void *user_data)
{
const struct io_info *info = data;
struct port *port = info->mix->port;
if (info->data) {
if (info->size >= sizeof(struct spa_io_async_buffers)) {
struct spa_io_async_buffers *ab = info->data;
info->mix->io[0] = &ab->buffers[port->direction];
info->mix->io[1] = &ab->buffers[port->direction^1];
} else if (info->size >= sizeof(struct spa_io_buffers)) {
info->mix->io[0] = info->data;
info->mix->io[1] = info->data;
} else {
info->mix->io[0] = NULL;
info->mix->io[1] = NULL;
}
if (port->n_mix++ == 0 && port->global_mix != NULL) {
port->global_mix->io[0] = &port->io[0];
port->global_mix->io[1] = &port->io[1];
}
} else {
info->mix->io[0] = NULL;
info->mix->io[1] = NULL;
if (port->n_mix > 0 && --port->n_mix == 0 && port->global_mix != NULL) {
port->global_mix->io[0] = NULL;
port->global_mix->io[1] = NULL;
}
}
return 0;
}
static inline void mix_set_io(struct mix *mix, void *data, size_t size)
{
struct io_info info = { .mix = mix, .data = data, .size = size };
pw_loop_locked(mix->port->client->loop->loop,
do_mix_set_io, SPA_ID_INVALID, &info, sizeof(info), NULL);
}
static void init_mix(struct mix *mix, uint32_t mix_id, struct port *port, uint32_t peer_id)
{
pw_log_debug("create %p mix:%d peer:%d", port, mix_id, peer_id);
mix->id = mix_id;
mix->peer_id = peer_id;
mix->port = port;
mix->peer_port = NULL;
mix->io[0] = mix->io[1] = NULL;
mix->n_buffers = 0;
spa_list_init(&mix->queue);
if (mix_id == SPA_ID_INVALID) {
port->global_mix = mix;
if (port->n_mix > 0)
mix_set_io(port->global_mix, &port->io, sizeof(port->io));
}
}
static struct mix *find_mix_peer(struct client *c, uint32_t peer_id)
{
struct mix *mix;
spa_list_for_each(mix, &c->mix, link) {
if (mix->peer_id == peer_id)
return mix;
}
return NULL;
}
static struct mix *find_port_peer(struct port *port, uint32_t peer_id)
{
struct mix *mix;
spa_list_for_each(mix, &port->mix, port_link) {
pw_log_trace("%p %d %d", port, mix->peer_id, peer_id);
if (mix->peer_id == peer_id)
return mix;
}
return NULL;
}
static struct mix *find_mix(struct client *c, struct port *port, uint32_t mix_id)
{
struct mix *mix;
spa_list_for_each(mix, &port->mix, port_link) {
if (mix->id == mix_id)
return mix;
}
return NULL;
}
static struct mix *create_mix(struct client *c, struct port *port,
uint32_t mix_id, uint32_t peer_id)
{
struct mix *mix;
uint32_t i;
if (spa_list_is_empty(&c->free_mix)) {
mix = calloc(OBJECT_CHUNK, sizeof(struct mix));
if (mix == NULL)
return NULL;
mix[0].to_free = true;
for (i = 0; i < OBJECT_CHUNK; i++)
spa_list_append(&c->free_mix, &mix[i].link);
}
mix = spa_list_first(&c->free_mix, struct mix, link);
spa_list_remove(&mix->link);
spa_list_append(&c->mix, &mix->link);
spa_list_append(&port->mix, &mix->port_link);
init_mix(mix, mix_id, port, peer_id);
return mix;
}
static int clear_buffers(struct client *c, struct mix *mix)
{
struct port *port = mix->port;
struct buffer *b;
uint32_t i, j;
pw_log_debug("%p: port %p clear buffers", c, port);
for (i = 0; i < mix->n_buffers; i++) {
b = &mix->buffers[i];
for (j = 0; j < b->n_mem; j++)
pw_memmap_free(b->mem[j]);
b->n_mem = 0;
}
mix->n_buffers = 0;
spa_list_init(&mix->queue);
return 0;
}
static void free_mix(struct client *c, struct mix *mix)
{
struct port *port = mix->port;
clear_buffers(c, mix);
spa_list_remove(&mix->port_link);
if (mix->id == SPA_ID_INVALID)
port->global_mix = NULL;
spa_list_remove(&mix->link);
spa_list_append(&c->free_mix, &mix->link);
}
static struct port * alloc_port(struct client *c, enum spa_direction direction)
{
struct port *p;
struct object *o;
uint32_t i, port_size;
if (c->n_ports >= c->max_ports) {
errno = ENOSPC;
return NULL;
}
if (spa_list_is_empty(&c->free_ports)) {
port_size = sizeof(struct port) + (c->max_frames * sizeof(float)) + c->max_align;
p = calloc(OBJECT_CHUNK, port_size);
if (p == NULL)
return NULL;
p[0].to_free = true;
for (i = 0; i < OBJECT_CHUNK; i++) {
struct port *t = SPA_PTROFF(p, port_size * i, struct port);
spa_list_append(&c->free_ports, &t->link);
}
}
p = spa_list_first(&c->free_ports, struct port, link);
spa_list_remove(&p->link);
o = alloc_object(c, INTERFACE_Port);
if (o == NULL)
return NULL;
o->id = SPA_ID_INVALID;
o->port.node_id = c->node_id;
o->port.port = p;
o->port.latency[SPA_DIRECTION_INPUT] = SPA_LATENCY_INFO(SPA_DIRECTION_INPUT);
o->port.latency[SPA_DIRECTION_OUTPUT] = SPA_LATENCY_INFO(SPA_DIRECTION_OUTPUT);
p->valid = true;
p->zeroed = false;
p->client = c;
p->object = o;
spa_list_init(&p->mix);
p->props = pw_properties_new(NULL, NULL);
p->direction = direction;
p->emptyptr = SPA_PTR_ALIGN(p->empty, c->max_align, float);
p->port_id = pw_map_insert_new(&c->ports[direction], p);
c->n_ports++;
pthread_mutex_lock(&c->context.lock);
spa_list_append(&c->context.objects, &o->link);
pthread_mutex_unlock(&c->context.lock);
return p;
}
static void free_port(struct client *c, struct port *p, bool free)
{
struct mix *m;
spa_list_consume(m, &p->mix, port_link)
free_mix(c, m);
c->n_ports--;
pw_map_remove(&c->ports[p->direction], p->port_id);
pw_properties_free(p->props);
spa_list_append(&c->free_ports, &p->link);
if (free)
free_object(c, p->object);
else
p->object->removing = true;
}
static struct object *find_node(struct client *c, const char *name)
{
struct object *o;
spa_list_for_each(o, &c->context.objects, link) {
if (o->removing || o->removed || o->type != INTERFACE_Node)
continue;
if (spa_streq(o->node.name, name))
return o;
}
return NULL;
}
static bool is_port_default(struct client *c, struct object *o)
{
struct object *ot;
if (c->metadata == NULL)
return false;
if ((ot = o->port.node) != NULL &&
(spa_streq(ot->node.node_name, c->metadata->default_audio_source) ||
spa_streq(ot->node.node_name, c->metadata->default_audio_sink)))
return true;
return false;
}
static inline bool client_port_visible(struct client *c, struct object *o)
{
if (o->port.port != NULL && o->port.port->client == c)
return true;
return o->visible;
}
static struct object *find_port_by_name(struct client *c, const char *name)
{
struct object *o;
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Port || o->removed ||
(!client_port_visible(c, o)))
continue;
if (spa_streq(o->port.name, name) ||
spa_streq(o->port.alias1, name) ||
spa_streq(o->port.alias2, name))
return o;
if (is_port_default(c, o) && spa_streq(o->port.system, name))
return o;
}
return NULL;
}
static struct object *find_by_id(struct client *c, uint32_t id)
{
struct object *o;
spa_list_for_each(o, &c->context.objects, link) {
if (o->id == id)
return o;
}
return NULL;
}
static struct object *find_by_serial(struct client *c, uint32_t serial)
{
struct object *o;
spa_list_for_each(o, &c->context.objects, link) {
if (o->serial == serial)
return o;
}
return NULL;
}
static struct object *find_id(struct client *c, uint32_t id, bool valid)
{
struct object *o = find_by_id(c, id);
if (o != NULL && (!valid || o->client == c))
return o;
return NULL;
}
static struct object *find_type(struct client *c, uint32_t id, uint32_t type, bool valid)
{
struct object *o = find_id(c, id, valid);
if (o != NULL && o->type == type)
return o;
return NULL;
}
static struct object *find_client(struct client *c, uint32_t client_id)
{
return find_type(c, client_id, INTERFACE_Client, false);
}
static struct object *find_link(struct client *c, uint32_t src, uint32_t dst)
{
struct object *l;
spa_list_for_each(l, &c->context.objects, link) {
if (l->type != INTERFACE_Link || l->removed)
continue;
if (l->port_link.src == src &&
l->port_link.dst == dst) {
return l;
}
}
return NULL;
}
#if defined (__SSE__)
#include <xmmintrin.h>
static void mix_sse(float *dst, float *src[], uint32_t n_src, bool aligned, uint32_t n_samples)
{
uint32_t i, n, unrolled;
__m128 in[1];
if (SPA_IS_ALIGNED(dst, 16) && aligned)
unrolled = n_samples & ~3;
else
unrolled = 0;
for (n = 0; n < unrolled; n += 4) {
in[0] = _mm_load_ps(&src[0][n]);
for (i = 1; i < n_src; i++)
in[0] = _mm_add_ps(in[0], _mm_load_ps(&src[i][n]));
_mm_store_ps(&dst[n], in[0]);
}
for (; n < n_samples; n++) {
in[0] = _mm_load_ss(&src[0][n]);
for (i = 1; i < n_src; i++)
in[0] = _mm_add_ss(in[0], _mm_load_ss(&src[i][n]));
_mm_store_ss(&dst[n], in[0]);
}
}
#endif
static void mix_c(float *dst, float *src[], uint32_t n_src, bool aligned, uint32_t n_samples)
{
uint32_t n, i;
for (n = 0; n < n_samples; n++) {
float t = src[0][n];
for (i = 1; i < n_src; i++)
t += src[i][n];
dst[n] = t;
}
}
SPA_EXPORT
void jack_get_version(int *major_ptr, int *minor_ptr, int *micro_ptr, int *proto_ptr)
{
if (major_ptr)
*major_ptr = 3;
if (minor_ptr)
*minor_ptr = PW_MAJOR;
if (micro_ptr)
*micro_ptr = PW_MINOR;
if (proto_ptr)
*proto_ptr = PW_MICRO;
}
#define do_callback_expr(c,expr,callback,do_emit,...) \
({ \
if (c->callback && do_emit) { \
pw_thread_loop_unlock(c->context.loop); \
if (c->locked_process) \
pthread_mutex_lock(&c->rt_lock); \
(expr); \
pw_log_debug("emit " #callback); \
c->callback(__VA_ARGS__); \
if (c->locked_process) \
pthread_mutex_unlock(&c->rt_lock); \
pw_thread_loop_lock(c->context.loop); \
} else { \
(expr); \
pw_log_debug("skip " #callback \
" cb:%p do_emit:%d", c->callback, \
do_emit); \
} \
})
#define do_callback(c,callback,do_emit,...) do_callback_expr(c,(void)0,callback,do_emit,__VA_ARGS__)
#define do_rt_callback_res(c,callback,...) \
({ \
int res = 0; \
if (c->callback) { \
if (pthread_mutex_trylock(&c->rt_lock) == 0) { \
c->rt_locked = true; \
res = c->callback(__VA_ARGS__); \
c->rt_locked = false; \
pthread_mutex_unlock(&c->rt_lock); \
} else { \
pw_log_debug("skip " #callback \
" cb:%p", c->callback); \
} \
} \
res; \
})
SPA_EXPORT
const char *
jack_get_version_string(void)
{
static char name[1024];
int major, minor, micro, proto;
jack_get_version(&major, &minor, &micro, &proto);
snprintf(name, sizeof(name), "%d.%d.%d.%d (using PipeWire %s)",
major, minor, micro, proto, pw_get_library_version());
return name;
}
#define freeze_callbacks(c) \
({ \
(c)->frozen_callbacks++; \
})
#define check_callbacks(c) \
({ \
if ((c)->frozen_callbacks == 0 && (c)->pending_callbacks) \
pw_loop_signal_event((c)->context.nl, (c)->notify_source); \
})
#define thaw_callbacks(c) \
({ \
(c)->frozen_callbacks--; \
check_callbacks(c); \
})
static void on_notify_event(void *data, uint64_t count)
{
struct client *c = data;
struct object *o;
int32_t avail;
uint32_t index;
struct notify *notify;
bool do_graph = false, do_recompute_capture = false, do_recompute_playback = false;
pw_thread_loop_lock(c->context.loop);
if (c->frozen_callbacks != 0 || !c->pending_callbacks)
goto done;
pw_log_debug("%p: enter active:%u", c, c->active);
c->pending_callbacks = false;
freeze_callbacks(c);
avail = spa_ringbuffer_get_read_index(&c->notify_ring, &index);
while (avail > 0) {
notify = SPA_PTROFF(c->notify_buffer, index & NOTIFY_BUFFER_MASK, struct notify);
o = notify->object;
pw_log_debug("%p: dequeue notify index:%08x %p type:%d %p arg1:%d", c,
index, notify, notify->type, o, notify->arg1);
switch (notify->type) {
case NOTIFY_TYPE_REGISTRATION:
if (o->registered == notify->arg1)
break;
pw_log_debug("%p: node %u %s %u", c, o->serial,
o->node.name, notify->arg1);
do_callback(c, registration_callback, true,
o->node.name,
notify->arg1,
c->registration_arg);
break;
case NOTIFY_TYPE_PORTREGISTRATION:
if (o->registered == notify->arg1)
break;
pw_log_debug("%p: port %u %s %u", c, o->serial,
o->port.name, notify->arg1);
do_callback(c, portregistration_callback, c->active,
o->serial,
notify->arg1,
c->portregistration_arg);
break;
case NOTIFY_TYPE_PORT_RENAME:
if (o->registered == notify->arg1)
break;
pw_log_debug("%p: port rename %u %s->%s", c, o->serial,
o->port.old_name, o->port.name);
do_callback(c, rename_callback, c->active,
o->serial,
o->port.old_name, o->port.name,
c->rename_arg);
break;
case NOTIFY_TYPE_CONNECT:
if (o->registered == notify->arg1)
break;
pw_log_debug("%p: link %u %u -> %u %u", c, o->serial,
o->port_link.src_serial,
o->port_link.dst, notify->arg1);
do_callback(c, connect_callback, c->active,
o->port_link.src_serial,
o->port_link.dst_serial,
notify->arg1,
c->connect_arg);
do_graph = true;
do_recompute_capture = do_recompute_playback = true;
break;
case NOTIFY_TYPE_BUFFER_FRAMES:
pw_log_debug("%p: buffer frames %d -> %d", c, c->buffer_frames, notify->arg1);
if (c->buffer_frames != (uint32_t)notify->arg1) {
do_callback_expr(c, c->buffer_frames = notify->arg1,
bufsize_callback, c->active,
notify->arg1, c->bufsize_arg);
do_recompute_capture = do_recompute_playback = true;
}
break;
case NOTIFY_TYPE_SAMPLE_RATE:
pw_log_debug("%p: sample rate %d -> %d", c, c->sample_rate, notify->arg1);
if (c->sample_rate != (uint32_t)notify->arg1) {
do_callback_expr(c, c->sample_rate = notify->arg1,
srate_callback, c->active,
notify->arg1, c->srate_arg);
}
break;
case NOTIFY_TYPE_FREEWHEEL:
pw_log_debug("%p: freewheel %d", c, notify->arg1);
do_callback(c, freewheel_callback, c->active,
notify->arg1, c->freewheel_arg);
break;
case NOTIFY_TYPE_SHUTDOWN:
pw_log_debug("%p: shutdown %d %s", c, notify->arg1, notify->msg);
if (c->info_shutdown_callback)
do_callback(c, info_shutdown_callback, c->active,
notify->arg1, notify->msg,
c->info_shutdown_arg);
else
do_callback(c, shutdown_callback, c->active, c->shutdown_arg);
break;
case NOTIFY_TYPE_LATENCY:
pw_log_debug("%p: latency %d", c, notify->arg1);
if (notify->arg1 == JackCaptureLatency)
do_recompute_capture = true;
else if (notify->arg1 == JackPlaybackLatency)
do_recompute_playback = true;
break;
case NOTIFY_TYPE_TOTAL_LATENCY:
pw_log_debug("%p: total latency", c);
do_recompute_capture = do_recompute_playback = true;
break;
default:
break;
}
if (o != NULL) {
o->registered = notify->arg1;
if (notify->arg1 == 0 && o->removing) {
o->removing = false;
free_object(c, o);
}
}
avail -= sizeof(struct notify);
index += sizeof(struct notify);
spa_ringbuffer_read_update(&c->notify_ring, index);
}
if (do_recompute_capture)
do_callback(c, latency_callback, c->active, JackCaptureLatency, c->latency_arg);
if (do_recompute_playback)
do_callback(c, latency_callback, c->active, JackPlaybackLatency, c->latency_arg);
if (do_graph)
do_callback(c, graph_callback, c->active, c->graph_arg);
thaw_callbacks(c);
done:
pw_log_debug("%p: leave", c);
pw_thread_loop_unlock(c->context.loop);
}
static int queue_notify(struct client *c, int type, struct object *o, int arg1, const char *msg)
{
int32_t filled;
uint32_t index;
struct notify *notify;
bool emit = false;
int res = 0;
switch (type) {
case NOTIFY_TYPE_REGISTRATION:
emit = c->registration_callback != NULL && o != NULL;
break;
case NOTIFY_TYPE_PORTREGISTRATION:
emit = c->portregistration_callback != NULL && o != NULL;
o->visible = arg1;
break;
case NOTIFY_TYPE_PORT_RENAME:
emit = c->rename_callback != NULL && o != NULL;
break;
case NOTIFY_TYPE_CONNECT:
emit = c->connect_callback != NULL && o != NULL;
break;
case NOTIFY_TYPE_BUFFER_FRAMES:
emit = c->bufsize_callback != NULL;
break;
case NOTIFY_TYPE_SAMPLE_RATE:
emit = c->srate_callback != NULL;
break;
case NOTIFY_TYPE_FREEWHEEL:
emit = c->freewheel_callback != NULL;
break;
case NOTIFY_TYPE_SHUTDOWN:
emit = c->info_shutdown_callback != NULL || c->shutdown_callback != NULL;
break;
case NOTIFY_TYPE_LATENCY:
case NOTIFY_TYPE_TOTAL_LATENCY:
emit = c->latency_callback != NULL;
break;
default:
break;
}
if (!emit || ((type & NOTIFY_ACTIVE_FLAG) && !c->active)) {
switch (type) {
case NOTIFY_TYPE_BUFFER_FRAMES:
if (!emit) {
c->buffer_frames = arg1;
queue_notify(c, NOTIFY_TYPE_TOTAL_LATENCY, NULL, 0, NULL);
}
break;
case NOTIFY_TYPE_SAMPLE_RATE:
if (!emit)
c->sample_rate = arg1;
break;
}
pw_log_debug("%p: skip notify %08x active:%d emit:%d", c, type,
c->active, emit);
if (o != NULL) {
o->registered = arg1;
if (arg1 == 0 && o->removing) {
o->removing = false;
free_object(c, o);
}
}
return res;
}
pthread_mutex_lock(&c->context.lock);
filled = spa_ringbuffer_get_write_index(&c->notify_ring, &index);
if (filled < 0 || filled + sizeof(struct notify) > NOTIFY_BUFFER_SIZE) {
pw_log_warn("%p: notify queue full %d", c, type);
res = -ENOSPC;
goto done;
}
notify = SPA_PTROFF(c->notify_buffer, index & NOTIFY_BUFFER_MASK, struct notify);
notify->type = type;
notify->object = o;
notify->arg1 = arg1;
notify->msg = msg;
pw_log_debug("%p: queue notify index:%08x %p type:%d %p arg1:%d msg:%s", c,
index, notify, notify->type, o, notify->arg1, notify->msg);
index += sizeof(struct notify);
spa_ringbuffer_write_update(&c->notify_ring, index);
c->pending_callbacks = true;
check_callbacks(c);
done:
pthread_mutex_unlock(&c->context.lock);
return res;
}
static void on_sync_reply(void *data, uint32_t id, int seq)
{
struct client *client = data;
if (id != PW_ID_CORE)
return;
client->last_sync = seq;
if (client->pending_sync == seq)
pw_thread_loop_signal(client->context.loop, false);
}
static void on_error(void *data, uint32_t id, int seq, int res, const char *message)
{
struct client *client = data;
pw_log_warn("%p: error id:%u seq:%d res:%d (%s): %s", client,
id, seq, res, spa_strerror(res), message);
if (id == PW_ID_CORE) {
/* This happens when we did something on a proxy that
* was destroyed on the server already */
if (res == -ENOENT)
return;
client->last_res = res;
if (res == -EPIPE && !client->destroyed) {
queue_notify(client, NOTIFY_TYPE_SHUTDOWN,
NULL, JackFailure | JackServerError,
"JACK server has been closed");
}
}
pw_thread_loop_signal(client->context.loop, false);
}
static const struct pw_core_events core_events = {
PW_VERSION_CORE_EVENTS,
.done = on_sync_reply,
.error = on_error,
};
static int do_sync(struct client *client)
{
bool in_data_thread = pw_data_loop_in_thread(client->loop);
if (pw_thread_loop_in_thread(client->context.loop)) {
pw_log_warn("sync requested from callback");
return 0;
}
if (client->last_res == -EPIPE)
return -EPIPE;
client->last_res = 0;
client->pending_sync = pw_proxy_sync((struct pw_proxy*)client->core, client->pending_sync);
if (client->pending_sync < 0)
return client->pending_sync;
while (true) {
if (in_data_thread) {
if (client->rt_locked)
pthread_mutex_unlock(&client->rt_lock);
client->data_locked = true;
}
pw_thread_loop_wait(client->context.loop);
if (in_data_thread) {
client->data_locked = false;
if (client->rt_locked)
pthread_mutex_lock(&client->rt_lock);
}
if (client->last_res < 0)
return client->last_res;
if (client->pending_sync == client->last_sync)
break;
}
return 0;
}
static void on_node_removed(void *data)
{
struct client *client = data;
pw_proxy_destroy((struct pw_proxy*)client->node);
}
static void on_node_destroy(void *data)
{
struct client *client = data;
client->node = NULL;
spa_hook_remove(&client->proxy_listener);
spa_hook_remove(&client->node_listener);
}
static void on_node_bound_props(void *data, uint32_t global_id, const struct spa_dict *props)
{
struct client *client = data;
client->node_id = global_id;
if (props)
pw_properties_update(client->props, props);
}
static const struct pw_proxy_events node_proxy_events = {
PW_VERSION_PROXY_EVENTS,
.removed = on_node_removed,
.destroy = on_node_destroy,
.bound_props = on_node_bound_props,
};
static struct link *find_activation(struct spa_list *links, uint32_t node_id)
{
struct link *l;
spa_list_for_each(l, links, link) {
if (l->node_id == node_id)
return l;
}
return NULL;
}
static void client_remove_source(struct client *c)
{
if (c->socket_source) {
pw_loop_destroy_source(c->l, c->socket_source);
c->socket_source = NULL;
}
}
static inline void queue_buffer(struct client *c, struct mix *mix, uint32_t id)
{
struct buffer *b;
b = &mix->buffers[id];
if (SPA_FLAG_IS_SET(b->flags, BUFFER_FLAG_OUT)) {
pw_log_trace_fp("%p: port %p: recycle buffer %d", c, mix->port, id);
spa_list_append(&mix->queue, &b->link);
SPA_FLAG_CLEAR(b->flags, BUFFER_FLAG_OUT);
}
}
static inline struct buffer *dequeue_buffer(struct client *c, struct mix *mix)
{
struct buffer *b;
if (SPA_UNLIKELY(spa_list_is_empty(&mix->queue)))
return NULL;
b = spa_list_first(&mix->queue, struct buffer, link);
spa_list_remove(&b->link);
SPA_FLAG_SET(b->flags, BUFFER_FLAG_OUT);
pw_log_trace_fp("%p: port %p: dequeue buffer %d", c, mix->port, b->id);
return b;
}
static inline bool is_osc(jack_midi_event_t *ev)
{
return ev->size >= 1 && (ev->buffer[0] == '#' || ev->buffer[0] == '/');
}
static size_t convert_from_event(void *midi, void *buffer, size_t size, uint32_t type)
{
struct spa_pod_builder b = { 0, };
uint32_t i, count;
struct spa_pod_frame f;
uint32_t event_type;
switch (type) {
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
/* we handle MIDI as OSC, check below */
event_type = SPA_CONTROL_OSC;
break;
case TYPE_ID_UMP:
event_type = SPA_CONTROL_UMP;
break;
default:
return 0;
}
count = jack_midi_get_event_count(midi);
spa_pod_builder_init(&b, buffer, size);
spa_pod_builder_push_sequence(&b, &f, 0);
for (i = 0; i < count; i++) {
jack_midi_event_t ev;
jack_midi_event_get(&ev, midi, i);
if (type != TYPE_ID_MIDI || is_osc(&ev)) {
/* no midi port or it's OSC */
spa_pod_builder_control(&b, ev.time, event_type);
spa_pod_builder_bytes(&b, ev.buffer, ev.size);
} else {
/* midi port and it's not OSC, convert to UMP */
uint8_t *data = ev.buffer;
size_t size = ev.size;
uint64_t state = 0;
while (size > 0) {
uint32_t ump[4];
int ump_size = spa_ump_from_midi(&data, &size,
ump, sizeof(ump), 0, &state);
if (ump_size <= 0)
break;
spa_pod_builder_control(&b, ev.time, SPA_CONTROL_UMP);
spa_pod_builder_bytes(&b, ump, ump_size);
}
}
}
spa_pod_builder_pop(&b, &f);
return b.state.offset;
}
static inline int event_compare(uint8_t s1, uint8_t s2)
{
/* 11 (controller) > 12 (program change) >
* 8 (note off) > 9 (note on) > 10 (aftertouch) >
* 13 (channel pressure) > 14 (pitch bend) */
static int priotab[] = { 5,4,3,7,6,2,1,0 };
if ((s1 & 0xf) != (s2 & 0xf))
return 0;
return priotab[(s2>>4) & 7] - priotab[(s1>>4) & 7];
}
static inline int event_sort(struct spa_pod_control *a, const void *abody,
struct spa_pod_control *b, const void *bbody)
{
if (a->offset < b->offset)
return -1;
if (a->offset > b->offset)
return 1;
if (a->type != b->type)
return 0;
switch(a->type) {
case SPA_CONTROL_Midi:
{
const uint8_t *sa = abody, *sb = bbody;
if (SPA_POD_BODY_SIZE(&a->value) < 1 || SPA_POD_BODY_SIZE(&b->value) < 1)
return 0;
return event_compare(sa[0], sb[0]);
}
case SPA_CONTROL_UMP:
{
const uint32_t *sa = abody, *sb = bbody;
if (SPA_POD_BODY_SIZE(&a->value) < 4 || SPA_POD_BODY_SIZE(&b->value) < 4)
return 0;
if ((sa[0] >> 28) != 2 || (sa[0] >> 28) != 4 ||
(sb[0] >> 28) != 2 || (sb[0] >> 28) != 4)
return 0;
return event_compare(sa[0] >> 16, sb[0] >> 16);
}
default:
return 0;
}
}
static inline void fix_midi_event(uint8_t *data, size_t size)
{
/* fixup NoteOn with vel 0 */
if (size > 2 && (data[0] & 0xF0) == 0x90 && data[2] == 0x00) {
data[0] = 0x80 + (data[0] & 0x0F);
data[2] = 0x40;
}
}
static inline jack_midi_data_t* midi_event_reserve(void *port_buffer,
jack_nframes_t time, size_t data_size)
{
struct midi_buffer *mb = port_buffer;
uint8_t *res = NULL;
/* Check if data_size is >0 and there is enough space in the buffer for the event. */
if (SPA_UNLIKELY(data_size <= 0)) {
pw_log_warn("midi %p: data_size:%zd", port_buffer, data_size);
} else if (SPA_UNLIKELY(jack_midi_max_event_size (port_buffer) < data_size)) {
pw_log_warn("midi %p: event too large: data_size:%zd", port_buffer, data_size);
} else {
struct midi_event *events = SPA_PTROFF(mb, sizeof(*mb), struct midi_event);
struct midi_event *ev = &events[mb->event_count];
ev->time = time;
ev->size = data_size;
if (SPA_LIKELY(data_size <= MIDI_INLINE_MAX)) {
res = ev->inline_data;
} else {
mb->write_pos += data_size;
ev->byte_offset = mb->buffer_size - mb->write_pos;
res = SPA_PTROFF(mb, ev->byte_offset, uint8_t);
}
mb->event_count += 1;
}
return res;
}
static inline int midi_event_append(void *port_buffer, const jack_midi_data_t *data, size_t data_size)
{
struct midi_buffer *mb = port_buffer;
struct midi_event *events = SPA_PTROFF(mb, sizeof(*mb), struct midi_event);
struct midi_event *ev;
size_t old_size;
uint8_t *old, *buf;
ev = &events[--mb->event_count];
mb->write_pos -= ev->size;
old_size = ev->size;
if (old_size <= MIDI_INLINE_MAX)
old = ev->inline_data;
else
old = SPA_PTROFF(mb, ev->byte_offset, uint8_t);
buf = midi_event_reserve(port_buffer, ev->time, old_size + data_size);
if (SPA_UNLIKELY(buf == NULL))
return -ENOBUFS;
memmove(buf, old, old_size);
memcpy(buf+old_size, data, data_size);
return 0;
}
static inline int midi_event_write(void *port_buffer,
jack_nframes_t time,
const jack_midi_data_t *data,
size_t data_size, bool fix)
{
jack_midi_data_t *retbuf = midi_event_reserve (port_buffer, time, data_size);
if (SPA_UNLIKELY(retbuf == NULL))
return -ENOBUFS;
memcpy (retbuf, data, data_size);
if (fix)
fix_midi_event(retbuf, data_size);
return 0;
}
static void convert_to_event(struct mix_info **mix, uint32_t n_mix, void *midi, bool fix, uint32_t type)
{
uint64_t state = 0;
uint32_t i;
int res = 0;
bool in_sysex = false;
while (true) {
struct mix_info *next = NULL;
uint32_t next_index = 0;
struct spa_pod_control *control;
size_t size;
uint8_t *data;
for (i = 0; i < n_mix; i++) {
struct mix_info *m = mix[i];
if (next == NULL || event_sort(&m->control, m->control_body,
&next->control, next->control_body) <= 0) {
next = m;
next_index = i;
}
}
if (SPA_UNLIKELY(next == NULL))
break;
control = &next->control;
data = (uint8_t*)next->control_body;
size = SPA_POD_BODY_SIZE(&control->value);
switch(control->type) {
case SPA_CONTROL_OSC:
if (!TYPE_ID_CAN_OSC(type))
break;
SPA_FALLTHROUGH;
case SPA_CONTROL_Midi:
{
if (type == TYPE_ID_UMP) {
while (size > 0) {
uint32_t ump[4];
int ump_size = spa_ump_from_midi(&data, &size, ump, sizeof(ump), 0, &state);
if (ump_size <= 0)
break;
if ((res = midi_event_write(midi, control->offset,
(uint8_t*)ump, ump_size, false)) < 0)
break;
}
} else {
res = midi_event_write(midi, control->offset, data, size, fix);
}
if (res < 0)
pw_log_warn("midi %p: can't write event: %s", midi,
spa_strerror(res));
break;
}
case SPA_CONTROL_UMP:
{
uint8_t ev[32];
bool was_sysex = in_sysex;
if (type == TYPE_ID_MIDI) {
uint32_t *d = (uint32_t*)data;
int ev_size = spa_ump_to_midi(d, size, ev, sizeof(ev));
if (ev_size <= 0)
break;
size = ev_size;
data = ev;
if (!in_sysex && ev[0] == 0xf0)
in_sysex = true;
if (in_sysex && ev[ev_size-1] == 0xf7)
in_sysex = false;
} else if (type != TYPE_ID_UMP)
break;
if (was_sysex)
res = midi_event_append(midi, data, size);
else
res = midi_event_write(midi, control->offset, data, size, fix);
if (res < 0)
pw_log_warn("midi %p: can't write event: %s", midi,
spa_strerror(res));
}
}
if (spa_pod_parser_get_control_body(&next->parser,
&next->control, &next->control_body) < 0) {
spa_pod_parser_pop(&next->parser, &next->frame);
mix[next_index] = mix[--n_mix];
}
}
}
static inline void *get_buffer_output(struct port *p, uint32_t frames, uint32_t stride, struct buffer **buf)
{
struct mix *mix;
struct client *c = p->client;
void *ptr = NULL;
struct buffer *b;
struct spa_data *d;
struct spa_io_buffers *io;
uint32_t cycle = p->client->rt.position->clock.cycle & 1;
if (frames == 0 || !p->valid)
return NULL;
if (SPA_UNLIKELY((mix = p->global_mix) == NULL))
return NULL;
pw_log_trace_fp("%p: port %s %d get buffer %d n_buffers:%d io:%p",
c, p->object->port.name, p->port_id, frames,
mix->n_buffers, mix->io);
if (SPA_UNLIKELY((io = mix->io[cycle]) == NULL || mix->n_buffers == 0))
return NULL;
if (io->status == SPA_STATUS_HAVE_DATA &&
io->buffer_id < mix->n_buffers) {
b = &mix->buffers[io->buffer_id];
d = &b->datas[0];
} else {
if (mix->n_buffers == 1) {
b = &mix->buffers[0];
} else {
if (io->buffer_id < mix->n_buffers)
queue_buffer(c, mix, io->buffer_id);
b = dequeue_buffer(c, mix);
if (SPA_UNLIKELY(b == NULL)) {
pw_log_warn("port %p: out of buffers %d", p, mix->n_buffers);
io->buffer_id = SPA_ID_INVALID;
return NULL;
}
}
d = &b->datas[0];
d->chunk->offset = 0;
d->chunk->size = c->buffer_frames * sizeof(float);
d->chunk->stride = stride;
io->buffer_id = b->id;
io->status = SPA_STATUS_HAVE_DATA;
}
ptr = d->data;
if (buf)
*buf = b;
return ptr;
}
static inline void process_empty(struct port *p, uint32_t frames)
{
struct client *c = p->client;
void *ptr, *src = p->emptyptr;
struct port *tied = p->tied;
uint32_t type = p->object->port.type_id;
if (SPA_UNLIKELY(tied != NULL)) {
if ((src = tied->get_buffer(tied, frames)) == NULL)
src = p->emptyptr;
}
switch (type) {
case TYPE_ID_AUDIO:
ptr = get_buffer_output(p, frames, sizeof(float), NULL);
if (SPA_LIKELY(ptr != NULL))
memcpy(ptr, src, frames * sizeof(float));
break;
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
{
struct buffer *b;
ptr = get_buffer_output(p, c->max_frames, 1, &b);
if (SPA_LIKELY(ptr != NULL)) {
/* first build the complete pod in scratch memory, then copy it
* to the target buffer. This makes it possible for multiple threads
* to do this concurrently */
b->datas[0].chunk->size = convert_from_event(src, midi_scratch,
MIDI_SCRATCH_FRAMES * sizeof(float), type);
memcpy(ptr, midi_scratch, b->datas[0].chunk->size);
}
break;
}
default:
pw_log_warn("port %p: unhandled format %d", p, p->object->port.type_id);
break;
}
}
static void prepare_output(struct port *p, uint32_t frames, uint32_t cycle)
{
struct mix *mix;
struct spa_io_buffers *io;
if (SPA_UNLIKELY(p->empty_out || p->tied))
process_empty(p, frames);
if (p->global_mix == NULL || (io = p->global_mix->io[cycle]) == NULL)
return;
spa_list_for_each(mix, &p->mix, port_link) {
if (SPA_LIKELY(mix->io[cycle] != NULL))
*mix->io[cycle] = *io;
}
}
static void complete_process(struct client *c, uint32_t frames)
{
struct port *p;
struct mix *mix;
union pw_map_item *item;
uint32_t cycle = c->rt.position->clock.cycle & 1;
pw_array_for_each(item, &c->ports[SPA_DIRECTION_OUTPUT].items) {
if (pw_map_item_is_free(item))
continue;
p = item->data;
if (!p->valid)
continue;
prepare_output(p, frames, cycle);
p->io[cycle].status = SPA_STATUS_NEED_DATA;
}
pw_array_for_each(item, &c->ports[SPA_DIRECTION_INPUT].items) {
if (pw_map_item_is_free(item))
continue;
p = item->data;
if (!p->valid)
continue;
spa_list_for_each(mix, &p->mix, port_link) {
if (SPA_LIKELY(mix->io[cycle] != NULL))
mix->io[cycle]->status = SPA_STATUS_NEED_DATA;
}
}
}
static inline void debug_position(struct client *c, jack_position_t *p)
{
#define pw_log_custom pw_log_trace_fp
pw_log_custom("usecs: %"PRIu64, p->usecs);
pw_log_custom("frame_rate: %u", p->frame_rate);
pw_log_custom("frame: %u", p->frame);
pw_log_custom("valid: %08x", p->valid);
if (p->valid & JackPositionBBT) {
pw_log_custom("BBT");
pw_log_custom(" bar: %u", p->bar);
pw_log_custom(" beat: %u", p->beat);
pw_log_custom(" tick: %u", p->tick);
pw_log_custom(" bar_start_tick: %f", p->bar_start_tick);
pw_log_custom(" beats_per_bar: %f", p->beats_per_bar);
pw_log_custom(" beat_type: %f", p->beat_type);
pw_log_custom(" ticks_per_beat: %f", p->ticks_per_beat);
pw_log_custom(" beats_per_minute: %f", p->beats_per_minute);
}
if (p->valid & JackPositionTimecode) {
pw_log_custom("Timecode:");
pw_log_custom(" frame_time: %f", p->frame_time);
pw_log_custom(" next_time: %f", p->next_time);
}
if (p->valid & JackBBTFrameOffset) {
pw_log_custom("BBTFrameOffset:");
pw_log_custom(" bbt_offset: %u", p->bbt_offset);
}
if (p->valid & JackAudioVideoRatio) {
pw_log_custom("AudioVideoRatio:");
pw_log_custom(" audio_frames_per_video_frame: %f", p->audio_frames_per_video_frame);
}
if (p->valid & JackVideoFrameOffset) {
pw_log_custom("JackVideoFrameOffset:");
pw_log_custom(" video_offset: %u", p->video_offset);
}
#undef pw_log_custom
}
static inline void jack_to_position(jack_position_t *s, struct pw_node_activation *a)
{
struct spa_io_segment *d = &a->segment;
if (s->valid & JackPositionBBT) {
d->bar.flags = SPA_IO_SEGMENT_BAR_FLAG_VALID;
if (s->valid & JackBBTFrameOffset)
d->bar.offset = s->bbt_offset;
else
d->bar.offset = 0;
d->bar.signature_num = s->beats_per_bar;
d->bar.signature_denom = s->beat_type;
d->bar.ticks_per_beat = s->ticks_per_beat;
d->bar.bar_start_tick = s->bar_start_tick;
d->bar.bpm = s->beats_per_minute;
d->bar.beat = s->bar * s->beats_per_bar + (s->beat-1) +
(s->tick / s->ticks_per_beat);
}
}
static inline jack_transport_state_t position_to_jack(struct pw_node_activation *a,
jack_position_t *d, struct frame_times *t)
{
struct spa_io_position *s = &a->position;
jack_transport_state_t state;
struct spa_io_segment *seg = &s->segments[0];
uint64_t running;
switch (s->state) {
default:
case SPA_IO_POSITION_STATE_STOPPED:
state = JackTransportStopped;
break;
case SPA_IO_POSITION_STATE_STARTING:
state = JackTransportStarting;
break;
case SPA_IO_POSITION_STATE_RUNNING:
if (seg->flags & SPA_IO_SEGMENT_FLAG_LOOPING)
state = JackTransportLooping;
else
state = JackTransportRolling;
break;
}
if (SPA_UNLIKELY(d == NULL))
return state;
d->unique_1++;
t->frames = s->clock.position;
t->nsec = s->clock.nsec;
d->usecs = t->nsec / SPA_NSEC_PER_USEC;
t->next_nsec = s->clock.next_nsec;
t->rate_diff = s->clock.rate_diff;
t->buffer_frames = s->clock.duration;
d->frame_rate = t->sample_rate = s->clock.rate.denom;
if ((int64_t)s->clock.position < s->offset) {
d->frame = seg->position;
} else {
running = s->clock.position - s->offset;
if (running >= seg->start &&
(seg->duration == 0 || running < seg->start + seg->duration))
d->frame = (unsigned int)((running - seg->start) * seg->rate + seg->position);
else
d->frame = seg->position;
}
d->valid = 0;
if (a->segment_owner[0] && SPA_FLAG_IS_SET(seg->bar.flags, SPA_IO_SEGMENT_BAR_FLAG_VALID)) {
double abs_beat;
long beats;
d->valid |= JackPositionBBT;
d->bbt_offset = seg->bar.offset;
if (seg->bar.offset)
d->valid |= JackBBTFrameOffset;
d->beats_per_bar = seg->bar.signature_num;
d->beat_type = seg->bar.signature_denom;
d->ticks_per_beat = seg->bar.ticks_per_beat;
d->bar_start_tick = seg->bar.bar_start_tick;
d->beats_per_minute = seg->bar.bpm;
abs_beat = seg->bar.beat;
d->bar = (int32_t) (abs_beat / d->beats_per_bar);
beats = (long int) (d->bar * d->beats_per_bar);
d->beat = (int32_t) (abs_beat - beats);
beats += d->beat;
d->tick = (int32_t) ((abs_beat - beats) * d->ticks_per_beat);
d->beat++;
}
d->unique_2 = d->unique_1;
return state;
}
static inline int check_buffer_frames(struct client *c, struct spa_io_position *pos)
{
uint32_t buffer_frames = pos->clock.duration;
if (SPA_UNLIKELY(buffer_frames != c->buffer_frames)) {
pw_log_info("%p: bufferframes old:%d new:%d cb:%p", c,
c->buffer_frames, buffer_frames, c->bufsize_callback);
if (c->buffer_frames != (uint32_t)-1)
queue_notify(c, NOTIFY_TYPE_BUFFER_FRAMES, NULL, buffer_frames, NULL);
else
c->buffer_frames = buffer_frames;
}
return c->buffer_frames == buffer_frames;
}
static inline int check_sample_rate(struct client *c, struct spa_io_position *pos)
{
uint32_t sample_rate = pos->clock.rate.denom;
if (SPA_UNLIKELY(sample_rate != c->sample_rate)) {
pw_log_info("%p: sample_rate old:%d new:%d cb:%p", c,
c->sample_rate, sample_rate, c->srate_callback);
if (c->sample_rate != (uint32_t)-1)
queue_notify(c, NOTIFY_TYPE_SAMPLE_RATE, NULL, sample_rate, NULL);
else
c->sample_rate = sample_rate;
}
return c->sample_rate == sample_rate;
}
static inline uint32_t cycle_run(struct client *c)
{
uint64_t cmd;
int fd = c->socket_source->fd;
struct spa_io_position *pos = c->rt.position;
struct pw_node_activation *activation = c->activation;
struct pw_node_activation *driver = c->rt.driver_activation;
while (true) {
if (SPA_UNLIKELY(read(fd, &cmd, sizeof(cmd)) != sizeof(cmd))) {
if (errno == EINTR)
continue;
if (errno == EWOULDBLOCK || errno == EAGAIN)
return 0;
pw_log_warn("%p: read failed %m", c);
}
break;
}
if (SPA_UNLIKELY(cmd > 1)) {
pw_log_info("%p: missed %"PRIu64" wakeups", c, cmd - 1);
activation->xrun_count += cmd - 1;
activation->xrun_time = activation->awake_time;
activation->xrun_delay = 0;
activation->max_delay = SPA_MAX(activation->max_delay, 0u);
}
if (!SPA_ATOMIC_CAS(activation->status,
PW_NODE_ACTIVATION_TRIGGERED,
PW_NODE_ACTIVATION_AWAKE))
return 0;
activation->awake_time = get_time_ns(c->l->system);
if (SPA_UNLIKELY(c->rt.first)) {
if (c->thread_init_callback)
c->thread_init_callback(c->thread_init_arg);
c->rt.first = false;
}
if (SPA_UNLIKELY(pos == NULL)) {
pw_log_error("%p: missing position", c);
return 0;
}
if (check_buffer_frames(c, pos) == 0)
return 0;
if (check_sample_rate(c, pos) == 0)
return 0;
if (SPA_LIKELY(driver)) {
c->jack_state = position_to_jack(driver, &c->jack_position, &c->jack_times);
if (SPA_UNLIKELY(activation->pending_sync)) {
if (c->sync_callback == NULL ||
c->sync_callback(c->jack_state, &c->jack_position, c->sync_arg))
activation->pending_sync = false;
}
if (SPA_UNLIKELY(c->xrun_count != driver->xrun_count &&
c->xrun_count != 0 && c->xrun_callback))
c->xrun_callback(c->xrun_arg);
c->xrun_count = driver->xrun_count;
}
pw_log_trace_fp("%p: wait %"PRIu64" frames:%d rate:%d pos:%d delay:%"PRIi64" corr:%f", c,
activation->awake_time, c->buffer_frames, c->sample_rate,
c->jack_position.frame, pos->clock.delay, pos->clock.rate_diff);
return c->buffer_frames;
}
static inline uint32_t cycle_wait(struct client *c)
{
int res;
uint32_t nframes;
do {
res = pw_data_loop_wait(c->loop, -1);
if (SPA_UNLIKELY(res <= 0)) {
pw_log_warn("%p: wait error %m", c);
return 0;
}
nframes = cycle_run(c);
} while (!nframes);
return nframes;
}
static void trigger_link_v1(struct link *l, uint64_t nsec)
{
struct client *c = l->client;
struct pw_node_activation *a = l->activation;
struct pw_node_activation_state *state = &a->state[0];
uint64_t cmd = 1;
pw_log_trace_fp("%p: link %p-%d %p %d/%d", c, l, l->node_id, state,
state->pending, state->required);
if (pw_node_activation_state_dec(state)) {
if (SPA_ATOMIC_CAS(a->status,
PW_NODE_ACTIVATION_NOT_TRIGGERED,
PW_NODE_ACTIVATION_TRIGGERED)) {
a->signal_time = nsec;
pw_log_trace_fp("%p: signal %p %p", c, l, state);
if (SPA_UNLIKELY(write(l->signalfd, &cmd, sizeof(cmd)) != sizeof(cmd)))
pw_log_warn("%p: write failed %m", c);
}
}
}
static void trigger_link_v0(struct link *l, uint64_t nsec)
{
struct client *c = l->client;
struct pw_node_activation *a = l->activation;
struct pw_node_activation_state *state = &a->state[0];
uint64_t cmd = 1;
pw_log_trace_fp("%p: link %p-%d %p %d/%d", c, l, l->node_id, state,
state->pending, state->required);
if (pw_node_activation_state_dec(state)) {
SPA_ATOMIC_STORE(a->status, PW_NODE_ACTIVATION_TRIGGERED);
a->signal_time = nsec;
pw_log_trace_fp("%p: signal %p %p", c, l, state);
if (SPA_UNLIKELY(write(l->signalfd, &cmd, sizeof(cmd)) != sizeof(cmd)))
pw_log_warn("%p: write failed %m", c);
}
}
static inline void deactivate_link(struct client *c, struct link *l, uint64_t trigger)
{
if (!c->async && trigger != 0)
l->trigger(l, trigger);
}
static inline void signal_sync(struct client *c)
{
uint64_t nsec;
struct link *l;
struct pw_node_activation *activation = c->activation;
int old_status;
complete_process(c, c->buffer_frames);
nsec = get_time_ns(c->l->system);
old_status = SPA_ATOMIC_XCHG(activation->status, PW_NODE_ACTIVATION_FINISHED);
activation->finish_time = nsec;
if (c->async || old_status != PW_NODE_ACTIVATION_AWAKE)
return;
spa_list_for_each(l, &c->rt.target_links, target_link)
l->trigger(l, nsec);
}
static inline void cycle_signal(struct client *c, int status)
{
struct pw_node_activation *driver = c->rt.driver_activation;
struct pw_node_activation *activation = c->activation;
if (SPA_LIKELY(status == 0)) {
if (c->timebase_callback && driver && driver->segment_owner[0] == c->node_id) {
if (activation->pending_new_pos ||
c->jack_state == JackTransportRolling ||
c->jack_state == JackTransportLooping) {
c->timebase_callback(c->jack_state,
c->buffer_frames,
&c->jack_position,
activation->pending_new_pos,
c->timebase_arg);
activation->pending_new_pos = false;
debug_position(c, &c->jack_position);
jack_to_position(&c->jack_position, activation);
}
}
}
signal_sync(c);
}
static void
on_rtsocket_condition(void *data, int fd, uint32_t mask)
{
struct client *c = data;
if (SPA_UNLIKELY(mask & (SPA_IO_ERR | SPA_IO_HUP))) {
pw_log_warn("%p: got error", c);
client_remove_source(c);
return;
}
if (SPA_UNLIKELY(c->thread_callback)) {
if (!c->rt.thread_entered) {
c->rt.thread_entered = true;
c->thread_callback(c->thread_arg);
}
} else if (SPA_LIKELY(mask & SPA_IO_IN)) {
uint32_t buffer_frames;
int status = 0;
buffer_frames = cycle_run(c);
if (buffer_frames > 0)
status = do_rt_callback_res(c, process_callback, buffer_frames, c->process_arg);
cycle_signal(c, status);
}
}
static void free_link(struct link *link)
{
pw_log_debug("free link %p", link);
pw_memmap_free(link->mem);
close(link->signalfd);
free(link);
}
static int
do_clean_transport(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
struct link *l;
pw_log_debug("%p: clean transport", c);
client_remove_source(c);
spa_list_consume(l, &c->rt.target_links, target_link)
spa_list_remove(&l->target_link);
return 0;
}
static void clean_transport(struct client *c)
{
struct link *l;
if (!c->has_transport)
return;
/* We assume the data-loop is unlocked now and can process our
* clean function. This is reasonable, the cleanup function is run when
* closing the client, which should join the data-thread. */
pw_data_loop_invoke(c->loop, do_clean_transport, 1, NULL, 0, true, c);
spa_list_consume(l, &c->links, link) {
spa_list_remove(&l->link);
free_link(l);
}
c->has_transport = false;
}
static int client_node_transport(void *data,
int readfd, int writefd,
uint32_t mem_id, uint32_t offset, uint32_t size)
{
struct client *c = (struct client *) data;
clean_transport(c);
c->mem = pw_mempool_map_id(c->pool, mem_id,
PW_MEMMAP_FLAG_READWRITE, offset, size, NULL);
if (c->mem == NULL) {
pw_log_debug("%p: can't map activation: %m", c);
return -errno;
}
c->activation = c->mem->ptr;
pw_log_debug("%p: create client transport with fds %d %d for node %u",
c, readfd, writefd, c->node_id);
c->activation->client_version = PW_VERSION_NODE_ACTIVATION;
close(writefd);
c->socket_source = pw_loop_add_io(c->l,
readfd,
SPA_IO_ERR | SPA_IO_HUP,
true, on_rtsocket_condition, c);
c->has_transport = true;
c->position = &c->activation->position;
pw_thread_loop_signal(c->context.loop, false);
return 0;
}
static int client_node_set_param(void *data,
uint32_t id, uint32_t flags,
const struct spa_pod *param)
{
struct client *c = (struct client *) data;
pw_proxy_error((struct pw_proxy*)c->node, -ENOTSUP, "not supported");
return -ENOTSUP;
}
static int install_timeowner(struct client *c)
{
struct pw_node_activation *a;
uint32_t owner;
if (!c->timebase_callback)
return 0;
if ((a = c->driver_activation) == NULL)
return -EIO;
pw_log_debug("%p: activation %p", c, a);
/* was ok */
owner = SPA_ATOMIC_LOAD(a->segment_owner[0]);
if (owner == c->node_id)
return 0;
/* try to become owner */
if (c->timeowner_conditional) {
if (!SPA_ATOMIC_CAS(a->segment_owner[0], 0, c->node_id)) {
pw_log_debug("%p: owner:%u id:%u", c, owner, c->node_id);
return -EBUSY;
}
} else {
SPA_ATOMIC_STORE(a->segment_owner[0], c->node_id);
}
pw_log_debug("%p: timebase installed for id:%u", c, c->node_id);
return 0;
}
static int
do_update_driver_activation(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
c->rt.position = c->position;
c->rt.driver_activation = c->driver_activation;
if (c->position) {
pw_log_debug("%p: driver:%d clock:%s", c,
c->driver_id, c->position->clock.name);
check_sample_rate(c, c->position);
check_buffer_frames(c, c->position);
}
return 0;
}
static int update_driver_activation(struct client *c)
{
jack_client_t *client = (jack_client_t*)c;
struct link *link;
bool freewheeling;
pw_log_debug("%p: driver %d", c, c->driver_id);
freewheeling = SPA_FLAG_IS_SET(c->position->clock.flags, SPA_IO_CLOCK_FLAG_FREEWHEEL);
if (c->freewheeling != freewheeling) {
jack_native_thread_t thr = jack_client_thread_id(client);
c->freewheeling = freewheeling;
if (freewheeling && thr) {
jack_drop_real_time_scheduling(thr);
}
queue_notify(c, NOTIFY_TYPE_FREEWHEEL, NULL, freewheeling, NULL);
if (!freewheeling && thr) {
jack_acquire_real_time_scheduling(thr,
jack_client_real_time_priority(client));
}
}
link = find_activation(&c->links, c->driver_id);
c->driver_activation = link ? link->activation : NULL;
pw_data_loop_invoke(c->loop,
do_update_driver_activation, SPA_ID_INVALID, NULL, 0, false, c);
install_timeowner(c);
return 0;
}
static int
do_memmap_free(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
struct pw_memmap *mm = *((struct pw_memmap **)data);
pw_log_trace("memmap %p free", mm);
pw_memmap_free(mm);
pw_core_set_paused(c->core, false);
return 0;
}
static int
do_queue_memmap_free(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
pw_loop_invoke(c->context.l, do_memmap_free, 0, data, size, false, c);
return 0;
}
static void queue_memmap_free(struct client *c, struct pw_memmap *mem)
{
if (mem != NULL) {
mem->tag[0] = SPA_ID_INVALID;
pw_core_set_paused(c->core, true);
pw_data_loop_invoke(c->loop,
do_queue_memmap_free, SPA_ID_INVALID, &mem, sizeof(&mem), false, c);
}
}
static int client_node_set_io(void *data,
uint32_t id,
uint32_t mem_id,
uint32_t offset,
uint32_t size)
{
struct client *c = (struct client *) data;
struct pw_memmap *old, *mm;
void *ptr;
uint32_t tag[5] = { c->node_id, id, };
old = pw_mempool_find_tag(c->pool, tag, sizeof(tag));
if (mem_id == SPA_ID_INVALID) {
mm = ptr = NULL;
} else {
mm = pw_mempool_map_id(c->pool, mem_id,
PW_MEMMAP_FLAG_READWRITE, offset, size, tag);
if (mm == NULL) {
pw_log_warn("%p: can't map memory id %u: %m", c, mem_id);
return -errno;
}
ptr = mm->ptr;
}
pw_log_debug("%p: set io %s %p", c,
spa_debug_type_find_name(spa_type_io, id), ptr);
switch (id) {
case SPA_IO_Position:
c->position = ptr;
c->driver_id = ptr ? c->position->clock.id : SPA_ID_INVALID;
update_driver_activation(c);
c->activation->active_driver_id = c->driver_id;
queue_memmap_free(c, old);
old = NULL;
break;
default:
break;
}
pw_memmap_free(old);
return 0;
}
static int client_node_event(void *data, const struct spa_event *event)
{
return -ENOTSUP;
}
static int do_prepare_client(struct spa_loop *loop, bool async, uint32_t seq,
const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
pw_log_debug("%p prepared:%d ", c, c->rt.prepared);
if (c->rt.prepared)
return 0;
SPA_ATOMIC_STORE(c->activation->status, PW_NODE_ACTIVATION_FINISHED);
pw_loop_update_io(c->l,
c->socket_source,
SPA_IO_IN | SPA_IO_ERR | SPA_IO_HUP);
c->rt.first = true;
c->rt.thread_entered = false;
c->rt.prepared = true;
return 0;
}
static int do_unprepare_client(struct spa_loop *loop, bool async, uint32_t seq,
const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
int old_state;
uint64_t trigger = 0;
struct link *l;
pw_log_debug("%p prepared:%d ", c, c->rt.prepared);
old_state = SPA_ATOMIC_XCHG(c->activation->status, PW_NODE_ACTIVATION_INACTIVE);
if (old_state != PW_NODE_ACTIVATION_FINISHED)
trigger = get_time_ns(c->l->system);
if (!c->rt.prepared)
return 0;
spa_list_for_each(l, &c->rt.target_links, target_link) {
if (!c->async && trigger != 0)
l->trigger(l, trigger);
}
pw_loop_update_io(c->l,
c->socket_source, SPA_IO_ERR | SPA_IO_HUP);
c->rt.prepared = false;
return 0;
}
static int client_node_command(void *data, const struct spa_command *command)
{
struct client *c = (struct client *) data;
pw_log_debug("%p: got command %d", c, SPA_COMMAND_TYPE(command));
switch (SPA_NODE_COMMAND_ID(command)) {
case SPA_NODE_COMMAND_Suspend:
case SPA_NODE_COMMAND_Pause:
if (c->started) {
pw_loop_locked(c->loop->loop,
do_unprepare_client, SPA_ID_INVALID, NULL, 0, c);
c->started = false;
}
break;
case SPA_NODE_COMMAND_Start:
if (!c->started) {
pw_loop_locked(c->loop->loop,
do_prepare_client, SPA_ID_INVALID, NULL, 0, c);
c->started = true;
}
break;
default:
pw_log_warn("%p: unhandled node command %d", c, SPA_COMMAND_TYPE(command));
pw_proxy_errorf((struct pw_proxy*)c->node, -ENOTSUP,
"unhandled command %d", SPA_COMMAND_TYPE(command));
}
return 0;
}
static int client_node_add_port(void *data,
enum spa_direction direction,
uint32_t port_id, const struct spa_dict *props)
{
struct client *c = (struct client *) data;
pw_proxy_error((struct pw_proxy*)c->node, -ENOTSUP, "add port not supported");
return -ENOTSUP;
}
static int client_node_remove_port(void *data,
enum spa_direction direction,
uint32_t port_id)
{
struct client *c = (struct client *) data;
pw_proxy_error((struct pw_proxy*)c->node, -ENOTSUP, "remove port not supported");
return -ENOTSUP;
}
static int param_enum_format(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
switch (p->object->port.type_id) {
case TYPE_ID_AUDIO:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_EnumFormat,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_audio),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_dsp),
SPA_FORMAT_AUDIO_format, SPA_POD_Id(SPA_AUDIO_FORMAT_DSP_F32));
break;
case TYPE_ID_UMP:
case TYPE_ID_OSC:
case TYPE_ID_MIDI:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_EnumFormat,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_application),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_control));
break;
case TYPE_ID_VIDEO:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_EnumFormat,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_video),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_dsp),
SPA_FORMAT_VIDEO_format, SPA_POD_Id(SPA_VIDEO_FORMAT_DSP_F32));
break;
default:
return -EINVAL;
}
return 1;
}
static int param_format(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
switch (p->object->port.type_id) {
case TYPE_ID_AUDIO:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_Format,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_audio),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_dsp),
SPA_FORMAT_AUDIO_format, SPA_POD_Id(SPA_AUDIO_FORMAT_DSP_F32));
break;
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_Format,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_application),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_control));
break;
case TYPE_ID_VIDEO:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_Format, SPA_PARAM_Format,
SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_video),
SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_dsp),
SPA_FORMAT_VIDEO_format, SPA_POD_Id(SPA_VIDEO_FORMAT_DSP_F32));
break;
default:
return -EINVAL;
}
return 1;
}
static int param_buffers(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
switch (p->object->port.type_id) {
case TYPE_ID_AUDIO:
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_ParamBuffers, SPA_PARAM_Buffers,
SPA_PARAM_BUFFERS_buffers, SPA_POD_CHOICE_RANGE_Int(1, 1, MAX_BUFFERS),
SPA_PARAM_BUFFERS_blocks, SPA_POD_Int(1),
SPA_PARAM_BUFFERS_size, SPA_POD_CHOICE_STEP_Int(
c->max_frames * sizeof(float),
sizeof(float),
INT32_MAX,
sizeof(float)),
SPA_PARAM_BUFFERS_stride, SPA_POD_Int(p->object->port.type_id == TYPE_ID_AUDIO ?
sizeof(float) : 1));
break;
case TYPE_ID_VIDEO:
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_ParamBuffers, SPA_PARAM_Buffers,
SPA_PARAM_BUFFERS_buffers, SPA_POD_CHOICE_RANGE_Int(1, 1, MAX_BUFFERS),
SPA_PARAM_BUFFERS_blocks, SPA_POD_Int(1),
SPA_PARAM_BUFFERS_size, SPA_POD_CHOICE_RANGE_Int(
320 * 240 * 4 * 4,
0,
INT32_MAX),
SPA_PARAM_BUFFERS_stride, SPA_POD_CHOICE_RANGE_Int(4, 4, INT32_MAX));
break;
default:
return -EINVAL;
}
return 1;
}
static int param_io(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_ParamIO, SPA_PARAM_IO,
SPA_PARAM_IO_id, SPA_POD_Id(SPA_IO_Buffers),
SPA_PARAM_IO_size, SPA_POD_Int(sizeof(struct spa_io_buffers)));
return 1;
}
static int param_io_async(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
*param = spa_pod_builder_add_object(b,
SPA_TYPE_OBJECT_ParamIO, SPA_PARAM_IO,
SPA_PARAM_IO_id, SPA_POD_Id(SPA_IO_AsyncBuffers),
SPA_PARAM_IO_size, SPA_POD_Int(sizeof(struct spa_io_async_buffers)));
return 1;
}
static int param_latency(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
*param = spa_latency_build(b, SPA_PARAM_Latency,
&p->object->port.latency[p->direction]);
return 1;
}
static int param_latency_other(struct client *c, struct port *p,
struct spa_pod **param, struct spa_pod_builder *b)
{
*param = spa_latency_build(b, SPA_PARAM_Latency,
&p->object->port.latency[SPA_DIRECTION_REVERSE(p->direction)]);
return 1;
}
/* called from thread-loop */
static int port_set_format(struct client *c, struct port *p,
uint32_t flags, const struct spa_pod *param)
{
struct spa_pod *params[7];
uint8_t buffer[4096];
struct spa_pod_builder b = SPA_POD_BUILDER_INIT(buffer, sizeof(buffer));
if (param == NULL) {
struct mix *mix;
pw_log_debug("%p: port %p clear format", c, p);
spa_list_for_each(mix, &p->mix, port_link)
clear_buffers(c, mix);
p->params[IDX_Format] = SPA_PARAM_INFO(SPA_PARAM_Format, SPA_PARAM_INFO_WRITE);
}
else {
struct spa_audio_info info = { 0 };
if (spa_format_parse(param, &info.media_type, &info.media_subtype) < 0)
return -EINVAL;
switch (info.media_type) {
case SPA_MEDIA_TYPE_audio:
{
if (info.media_subtype != SPA_MEDIA_SUBTYPE_dsp)
return -EINVAL;
if (spa_format_audio_dsp_parse(param, &info.info.dsp) < 0)
return -EINVAL;
if (info.info.dsp.format != SPA_AUDIO_FORMAT_DSP_F32)
return -EINVAL;
break;
}
case SPA_MEDIA_TYPE_application:
if (info.media_subtype != SPA_MEDIA_SUBTYPE_control)
return -EINVAL;
break;
case SPA_MEDIA_TYPE_video:
{
struct spa_video_info vinfo = { 0 };
if (info.media_subtype != SPA_MEDIA_SUBTYPE_dsp)
return -EINVAL;
if (spa_format_video_dsp_parse(param, &vinfo.info.dsp) < 0)
return -EINVAL;
if (vinfo.info.dsp.format != SPA_VIDEO_FORMAT_DSP_F32)
return -EINVAL;
break;
}
default:
return -EINVAL;
}
p->params[IDX_Format] = SPA_PARAM_INFO(SPA_PARAM_Format, SPA_PARAM_INFO_READWRITE);
}
pw_log_debug("port %s: update", p->object->port.name);
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PARAMS;
param_enum_format(c, p, &params[0], &b);
param_format(c, p, &params[1], &b);
param_buffers(c, p, &params[2], &b);
param_io(c, p, &params[3], &b);
param_io_async(c, p, &params[4], &b);
param_latency(c, p, &params[5], &b);
param_latency_other(c, p, &params[6], &b);
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_PARAMS |
PW_CLIENT_NODE_PORT_UPDATE_INFO,
SPA_N_ELEMENTS(params),
(const struct spa_pod **) params,
&p->info);
p->info.change_mask = 0;
return 0;
}
/* called from thread-loop */
static void port_update_latency(struct port *p)
{
struct client *c = p->client;
struct spa_pod *params[7];
uint8_t buffer[4096];
struct spa_pod_builder b = SPA_POD_BUILDER_INIT(buffer, sizeof(buffer));
param_enum_format(c, p, &params[0], &b);
param_format(c, p, &params[1], &b);
param_buffers(c, p, &params[2], &b);
param_io(c, p, &params[3], &b);
param_io_async(c, p, &params[4], &b);
param_latency(c, p, &params[5], &b);
param_latency_other(c, p, &params[6], &b);
pw_log_debug("port %s: update", p->object->port.name);
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PARAMS;
p->params[IDX_Latency].flags ^= SPA_PARAM_INFO_SERIAL;
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_PARAMS |
PW_CLIENT_NODE_PORT_UPDATE_INFO,
SPA_N_ELEMENTS(params),
(const struct spa_pod **) params,
&p->info);
p->info.change_mask = 0;
}
static void port_check_latency(struct port *p, const struct spa_latency_info *latency)
{
struct spa_latency_info *current;
struct client *c = p->client;
struct object *o = p->object;
current = &o->port.latency[latency->direction];
if (spa_latency_info_compare(current, latency) == 0)
return;
*current = *latency;
pw_log_info("%p: %s update %s latency %f-%f %d-%d %"PRIu64"-%"PRIu64, c,
o->port.name,
latency->direction == SPA_DIRECTION_INPUT ? "playback" : "capture",
latency->min_quantum, latency->max_quantum,
latency->min_rate, latency->max_rate,
latency->min_ns, latency->max_ns);
port_update_latency(p);
}
/* called from thread-loop */
static void default_latency(struct client *c, enum spa_direction direction,
struct spa_latency_info *latency)
{
enum spa_direction other;
union pw_map_item *item;
struct port *p;
other = SPA_DIRECTION_REVERSE(direction);
spa_latency_info_combine_start(latency, direction);
pw_array_for_each(item, &c->ports[other].items) {
if (pw_map_item_is_free(item))
continue;
p = item->data;
spa_latency_info_combine(latency, &p->object->port.latency[direction]);
}
spa_latency_info_combine_finish(latency);
}
/* called from thread-loop */
static void default_latency_callback(jack_latency_callback_mode_t mode, struct client *c)
{
struct spa_latency_info latency;
union pw_map_item *item;
enum spa_direction direction;
struct port *p;
if (mode == JackPlaybackLatency)
direction = SPA_DIRECTION_INPUT;
else
direction = SPA_DIRECTION_OUTPUT;
default_latency(c, direction, &latency);
pw_array_for_each(item, &c->ports[direction].items) {
if (pw_map_item_is_free(item))
continue;
p = item->data;
port_check_latency(p, &latency);
}
}
/* called from thread-loop */
static int port_set_latency(struct client *c, struct port *p,
uint32_t flags, const struct spa_pod *param)
{
struct spa_latency_info info;
jack_latency_callback_mode_t mode;
struct spa_latency_info *current;
int res;
if (param == NULL)
info = SPA_LATENCY_INFO(SPA_DIRECTION_REVERSE(p->direction));
else if ((res = spa_latency_parse(param, &info)) < 0)
return res;
if (info.direction == p->direction)
return 0;
current = &p->object->port.latency[info.direction];
if (spa_latency_info_compare(current, &info) == 0)
return 0;
*current = info;
pw_log_info("port %s: set %s latency %f-%f %d-%d %"PRIu64"-%"PRIu64, p->object->port.name,
info.direction == SPA_DIRECTION_INPUT ? "playback" : "capture",
info.min_quantum, info.max_quantum,
info.min_rate, info.max_rate,
info.min_ns, info.max_ns);
if (info.direction == SPA_DIRECTION_INPUT)
mode = JackPlaybackLatency;
else
mode = JackCaptureLatency;
if (c->latency_callback)
queue_notify(c, NOTIFY_TYPE_LATENCY, NULL, mode, NULL);
else
default_latency_callback(mode, c);
port_update_latency(p);
return 0;
}
/* called from thread-loop */
static int client_node_port_set_param(void *data,
enum spa_direction direction,
uint32_t port_id,
uint32_t id, uint32_t flags,
const struct spa_pod *param)
{
struct client *c = (struct client *) data;
struct port *p = GET_PORT(c, direction, port_id);
if (p == NULL || !p->valid)
return -EINVAL;
pw_log_info("client %p: port %s %d.%d id:%d (%s) %p", c, p->object->port.name,
direction, port_id, id,
spa_debug_type_find_name(spa_type_param, id), param);
switch (id) {
case SPA_PARAM_Format:
return port_set_format(c, p, flags, param);
break;
case SPA_PARAM_Latency:
return port_set_latency(c, p, flags, param);
default:
break;
}
return 0;
}
static void midi_init_buffer(void *data, uint32_t max_frames, uint32_t nframes)
{
struct midi_buffer *mb = data;
mb->magic = MIDI_BUFFER_MAGIC;
mb->buffer_size = max_frames * sizeof(float);
mb->nframes = nframes;
mb->write_pos = 0;
mb->event_count = 0;
mb->lost_events = 0;
}
static inline void *init_buffer(struct port *p, uint32_t nframes)
{
struct client *c = p->client;
void *data = p->emptyptr;
if (p->zeroed)
return data;
if (TYPE_ID_IS_EVENT(p->object->port.type_id)) {
struct midi_buffer *mb = data;
midi_init_buffer(data, c->max_frames, nframes);
pw_log_debug("port %p: init midi buffer size:%d frames:%d", p,
mb->buffer_size, nframes);
} else
memset(data, 0, c->max_frames * sizeof(float));
p->zeroed = true;
return data;
}
static int client_node_port_use_buffers(void *data,
enum spa_direction direction,
uint32_t port_id,
uint32_t mix_id,
uint32_t flags,
uint32_t n_buffers,
struct pw_client_node_buffer *buffers)
{
struct client *c = (struct client *) data;
struct port *p = GET_PORT(c, direction, port_id);
struct buffer *b;
uint32_t i, j, fl;
int res;
struct mix *mix;
if (p == NULL || !p->valid) {
res = -EINVAL;
goto done;
}
if ((mix = find_mix(c, p, mix_id)) == NULL) {
res = -ENOMEM;
goto done;
}
pw_log_debug("%p: port %p %d %d.%d use_buffers %d", c, p, direction,
port_id, mix_id, n_buffers);
if (n_buffers > MAX_BUFFERS) {
pw_log_error("%p: too many buffers %u > %u", c, n_buffers, MAX_BUFFERS);
res = -ENOSPC;
goto done;
}
fl = PW_MEMMAP_FLAG_READ;
/* Make the buffer writable when output. Some apps write to the input buffer
* so we want to make them writable as well if the option is selected.
* We can't use a PRIVATE mapping here because then we might not see changes
* in the buffer by other apps (see mmap man page). */
if (direction == SPA_DIRECTION_OUTPUT ||
(p->object->port.type_id != TYPE_ID_VIDEO && c->writable_input))
fl |= PW_MEMMAP_FLAG_WRITE;
/* clear previous buffers */
clear_buffers(c, mix);
for (i = 0; i < n_buffers; i++) {
off_t offset;
struct spa_buffer *buf;
struct pw_memmap *mm;
mm = pw_mempool_map_id(c->pool, buffers[i].mem_id,
fl, buffers[i].offset, buffers[i].size, NULL);
if (mm == NULL) {
pw_log_warn("%p: can't map memory id %u: %m", c, buffers[i].mem_id);
continue;
}
buf = buffers[i].buffer;
b = &mix->buffers[i];
b->id = i;
b->flags = 0;
b->n_mem = 0;
b->mem[b->n_mem++] = mm;
pw_log_debug("%p: add buffer id:%u offset:%u size:%u map:%p ptr:%p",
c, buffers[i].mem_id, buffers[i].offset,
buffers[i].size, mm, mm->ptr);
offset = 0;
for (j = 0; j < buf->n_metas; j++) {
struct spa_meta *m = &buf->metas[j];
offset += SPA_ROUND_UP_N(m->size, 8);
}
b->n_datas = SPA_MIN(buf->n_datas, MAX_BUFFER_DATAS);
for (j = 0; j < b->n_datas; j++) {
struct spa_data *d = &b->datas[j];
memcpy(d, &buf->datas[j], sizeof(struct spa_data));
d->chunk =
SPA_PTROFF(mm->ptr, offset + sizeof(struct spa_chunk) * j,
struct spa_chunk);
if (d->type == SPA_DATA_MemId) {
uint32_t mem_id = SPA_PTR_TO_UINT32(d->data);
struct pw_memblock *bm;
struct pw_memmap *bmm;
bm = pw_mempool_find_id(c->pool, mem_id);
if (bm == NULL) {
pw_log_error("%p: unknown buffer mem %u", c, mem_id);
res = -ENODEV;
goto done;
}
d->fd = bm->fd;
d->type = bm->type;
d->data = NULL;
bmm = pw_memblock_map(bm, fl, d->mapoffset, d->maxsize, NULL);
if (bmm == NULL) {
res = -errno;
pw_log_error("%p: failed to map buffer mem %m", c);
d->data = NULL;
goto done;
}
b->mem[b->n_mem++] = bmm;
d->data = bmm->ptr;
pw_log_debug("%p: data %d %u -> fd %d %d",
c, j, bm->id, bm->fd, d->maxsize);
} else if (d->type == SPA_DATA_MemPtr) {
int offs = SPA_PTR_TO_INT(d->data);
d->data = SPA_PTROFF(mm->ptr, offs, void);
d->fd = -1;
pw_log_debug("%p: data %d %u -> mem %p %d",
c, j, b->id, d->data, d->maxsize);
} else {
pw_log_warn("unknown buffer data type %d", d->type);
}
if (c->allow_mlock && mlock(d->data, d->maxsize) < 0) {
if (errno != ENOMEM || !mlock_warned) {
pw_log(c->warn_mlock ? SPA_LOG_LEVEL_WARN : SPA_LOG_LEVEL_DEBUG,
"%p: Failed to mlock memory %p %u: %s", c,
d->data, d->maxsize,
errno == ENOMEM ?
"This is not a problem but for best performance, "
"consider increasing RLIMIT_MEMLOCK" : strerror(errno));
mlock_warned |= errno == ENOMEM;
}
}
}
SPA_FLAG_SET(b->flags, BUFFER_FLAG_OUT);
if (direction == SPA_DIRECTION_OUTPUT)
queue_buffer(c, mix, b->id);
}
pw_log_debug("%p: have %d buffers", c, n_buffers);
mix->n_buffers = n_buffers;
res = 0;
done:
if (res < 0)
pw_proxy_errorf((struct pw_proxy*)c->node, res,
"port_use_buffers(%u:%u:%u): %s", direction, port_id,
mix_id, spa_strerror(res));
return res;
}
static int client_node_port_set_io(void *data,
enum spa_direction direction,
uint32_t port_id,
uint32_t mix_id,
uint32_t id,
uint32_t mem_id,
uint32_t offset,
uint32_t size)
{
struct client *c = (struct client *) data;
struct port *p = GET_PORT(c, direction, port_id);
struct pw_memmap *mm, *old;
struct mix *mix;
uint32_t tag[5] = { c->node_id, direction, port_id, mix_id, id };
void *ptr;
int res = 0;
if (p == NULL || !p->valid) {
res = -EINVAL;
goto exit;
}
if ((mix = find_mix(c, p, mix_id)) == NULL) {
res = -ENOMEM;
goto exit;
}
old = pw_mempool_find_tag(c->pool, tag, sizeof(tag));
if (mem_id == SPA_ID_INVALID) {
mm = ptr = NULL;
size = 0;
} else {
mm = pw_mempool_map_id(c->pool, mem_id,
PW_MEMMAP_FLAG_READWRITE, offset, size, tag);
if (mm == NULL) {
pw_log_warn("%p: can't map memory id %u: %m", c, mem_id);
res = -EINVAL;
goto exit_free;
}
ptr = mm->ptr;
}
pw_log_debug("%p: port %p mix:%d set io:%s id:%u ptr:%p", c, p, mix_id,
spa_debug_type_find_name(spa_type_io, id), id, ptr);
switch (id) {
case SPA_IO_Buffers:
case SPA_IO_AsyncBuffers:
mix_set_io(mix, ptr, size);
queue_memmap_free(c, old);
old = NULL;
break;
default:
break;
}
exit_free:
pw_memmap_free(old);
exit:
if (res < 0)
pw_proxy_errorf((struct pw_proxy*)c->node, res,
"port_set_io(%u:%u:%u %u): %s", direction, port_id,
mix_id, id, spa_strerror(res));
return res;
}
static int
do_add_link(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct link *link = user_data;
struct client *c = link->client;
pw_log_trace("link %p", link);
spa_list_append(&c->rt.target_links, &link->target_link);
return 0;
}
static int
do_remove_link(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct link *link = user_data;
struct client *c = link->client;
pw_log_trace("link %p", link);
spa_list_remove(&link->target_link);
if (c->rt.prepared) {
int old_state = SPA_ATOMIC_LOAD(c->activation->status);
uint64_t trigger = 0;
if (old_state != PW_NODE_ACTIVATION_FINISHED)
trigger = get_time_ns(c->l->system);
deactivate_link(c, link, trigger);
}
return 0;
}
static int
do_free_link(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
struct link *l = *((struct link **)data);
free_link(l);
pw_core_set_paused(c->core, false);
return 0;
}
static int
do_queue_free_link(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
pw_loop_invoke(c->context.l, do_free_link, 0, data, size, false, c);
return 0;
}
static void queue_free_link(struct client *c, struct link *l)
{
pw_core_set_paused(c->core, true);
pw_data_loop_invoke(c->loop,
do_queue_free_link, SPA_ID_INVALID, &l, sizeof(&l), false, c);
}
static int client_node_set_activation(void *data,
uint32_t node_id,
int signalfd,
uint32_t mem_id,
uint32_t offset,
uint32_t size)
{
struct client *c = (struct client *) data;
struct pw_memmap *mm;
struct link *link;
void *ptr;
int res = 0;
if (mem_id == SPA_ID_INVALID) {
mm = ptr = NULL;
size = 0;
}
else {
mm = pw_mempool_map_id(c->pool, mem_id,
PW_MEMMAP_FLAG_READWRITE, offset, size, NULL);
if (mm == NULL) {
pw_log_warn("%p: can't map memory id %u: %m", c, mem_id);
res = -EINVAL;
goto exit;
}
ptr = mm->ptr;
}
if (c->node_id == node_id) {
pw_log_debug("%p: our activation %u: %u %u %u %p", c, node_id,
mem_id, offset, size, ptr);
} else {
pw_log_debug("%p: set activation %u: %u %u %u %p", c, node_id,
mem_id, offset, size, ptr);
}
if (ptr) {
link = calloc(1, sizeof(struct link));
if (link == NULL) {
res = -errno;
goto exit;
}
link->client = c;
link->node_id = node_id;
link->mem = mm;
link->activation = ptr;
link->signalfd = signalfd;
link->trigger = link->activation->server_version < 1 ? trigger_link_v0 : trigger_link_v1;
spa_list_append(&c->links, &link->link);
pw_loop_locked(c->loop->loop,
do_add_link, SPA_ID_INVALID, NULL, 0, link);
}
else {
link = find_activation(&c->links, node_id);
if (link == NULL) {
res = -EINVAL;
goto exit;
}
spa_list_remove(&link->link);
pw_loop_locked(c->loop->loop,
do_remove_link, SPA_ID_INVALID, NULL, 0, link);
queue_free_link(c, link);
}
if (c->driver_id == node_id)
update_driver_activation(c);
exit:
if (res < 0)
pw_proxy_errorf((struct pw_proxy*)c->node, res,
"set_activation(%u): %s", node_id, spa_strerror(res));
return res;
}
static int client_node_port_set_mix_info(void *data,
enum spa_direction direction,
uint32_t port_id,
uint32_t mix_id,
uint32_t peer_id,
const struct spa_dict *props)
{
struct client *c = (struct client *) data;
struct port *p = GET_PORT(c, direction, port_id);
struct mix *mix;
int res = 0;
if (p == NULL || !p->valid) {
res = peer_id == SPA_ID_INVALID ? 0 : -EINVAL;
goto exit;
}
mix = find_mix(c, p, mix_id);
pw_log_debug("%p: port %p mix:%d peer_id:%u info:%p", c, p, mix_id,
peer_id, props);
if (peer_id == SPA_ID_INVALID) {
if (mix == NULL) {
res = -ENOENT;
goto exit;
}
free_mix(c, mix);
} else {
if (mix != NULL) {
res = -EEXIST;
goto exit;
}
mix = create_mix(c, p, mix_id, peer_id);
}
exit:
if (res < 0)
pw_proxy_errorf((struct pw_proxy*)c->node, res,
"set_mix_info(%u:%u:%u %u): %s", direction, port_id,
mix_id, peer_id, spa_strerror(res));
return res;
}
static const struct pw_client_node_events client_node_events = {
PW_VERSION_CLIENT_NODE_EVENTS,
.transport = client_node_transport,
.set_param = client_node_set_param,
.set_io = client_node_set_io,
.event = client_node_event,
.command = client_node_command,
.add_port = client_node_add_port,
.remove_port = client_node_remove_port,
.port_set_param = client_node_port_set_param,
.port_use_buffers = client_node_port_use_buffers,
.port_set_io = client_node_port_set_io,
.set_activation = client_node_set_activation,
.port_set_mix_info = client_node_port_set_mix_info,
};
#define CHECK(expression,label) \
do { \
if ((errno = expression) != 0) { \
res = -errno; \
pw_log_error(#expression ": %s", strerror(errno)); \
goto label; \
} \
} while(false);
static struct spa_thread *impl_create(void *object,
const struct spa_dict *props,
void *(*start)(void*), void *arg)
{
struct client *c = (struct client *) object;
struct spa_dict_item *items;
struct spa_dict copy;
char creator_ptr[64];
pw_log_info("create thread");
if (globals.creator != NULL) {
uint32_t i, n_items = props ? props->n_items : 0;
items = alloca((n_items + 1) * sizeof(*items));
for (i = 0; i < n_items; i++)
items[i] = props->items[i];
snprintf(creator_ptr, sizeof(creator_ptr), "pointer:%p", globals.creator);
items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_THREAD_CREATOR,
creator_ptr);
copy = SPA_DICT_INIT(items, n_items);
props = &copy;
}
return spa_thread_utils_create(c->context.old_thread_utils, props, start, arg);
}
static int impl_join(void *object,
struct spa_thread *thread, void **retval)
{
struct client *c = (struct client *) object;
pw_log_info("join thread");
return spa_thread_utils_join(c->context.old_thread_utils, thread, retval);
}
static int impl_acquire_rt(void *object, struct spa_thread *thread, int priority)
{
struct client *c = (struct client *) object;
return spa_thread_utils_acquire_rt(c->context.old_thread_utils, thread, priority);
}
static int impl_drop_rt(void *object, struct spa_thread *thread)
{
struct client *c = (struct client *) object;
return spa_thread_utils_drop_rt(c->context.old_thread_utils, thread);
}
static struct spa_thread_utils_methods thread_utils_impl = {
SPA_VERSION_THREAD_UTILS_METHODS,
.create = impl_create,
.join = impl_join,
.acquire_rt = impl_acquire_rt,
.drop_rt = impl_drop_rt,
};
static jack_port_type_id_t string_to_type(const char *port_type)
{
if (spa_streq(JACK_DEFAULT_AUDIO_TYPE, port_type))
return TYPE_ID_AUDIO;
else if (spa_streq(JACK_DEFAULT_VIDEO_TYPE, port_type))
return TYPE_ID_VIDEO;
else if (spa_streq(JACK_DEFAULT_MIDI_TYPE, port_type))
return TYPE_ID_MIDI;
else if (spa_streq(JACK_DEFAULT_OSC_TYPE, port_type))
return TYPE_ID_OSC;
else if (spa_streq(JACK_DEFAULT_UMP_TYPE, port_type))
return TYPE_ID_UMP;
else if (spa_streq("other", port_type))
return TYPE_ID_OTHER;
else
return SPA_ID_INVALID;
}
static const char* type_to_string(jack_port_type_id_t type_id)
{
switch(type_id) {
case TYPE_ID_AUDIO:
return JACK_DEFAULT_AUDIO_TYPE;
case TYPE_ID_VIDEO:
return JACK_DEFAULT_VIDEO_TYPE;
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
/* all returned as MIDI */
return JACK_DEFAULT_MIDI_TYPE;
case TYPE_ID_OTHER:
return "other";
default:
return NULL;
}
}
static bool type_is_dsp(jack_port_type_id_t type_id)
{
switch(type_id) {
case TYPE_ID_AUDIO:
case TYPE_ID_MIDI:
case TYPE_ID_VIDEO:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
return true;
default:
return false;
}
}
static jack_uuid_t client_make_uuid(uint32_t id, bool monitor)
{
jack_uuid_t uuid = 0x2; /* JackUUIDClient */
uuid = (uuid << 32) | (id + 1);
if (monitor)
uuid |= (1 << 30);
pw_log_debug("uuid %d -> %"PRIu64, id, uuid);
return uuid;
}
static int metadata_property(void *data, uint32_t id,
const char *key, const char *type, const char *value)
{
struct client *c = (struct client *) data;
struct object *o;
jack_uuid_t uuid;
pw_log_debug("set id:%u key:'%s' value:'%s' type:'%s'", id, key, value, type);
if (id == PW_ID_CORE) {
if (key == NULL || spa_streq(key, "default.audio.sink")) {
if (value != NULL) {
if (spa_json_str_object_find(value, strlen(value), "name",
c->metadata->default_audio_sink,
sizeof(c->metadata->default_audio_sink)) < 0)
value = NULL;
}
if (value == NULL)
c->metadata->default_audio_sink[0] = '\0';
}
if (key == NULL || spa_streq(key, "default.audio.source")) {
if (value != NULL) {
if (spa_json_str_object_find(value, strlen(value), "name",
c->metadata->default_audio_source,
sizeof(c->metadata->default_audio_source)) < 0)
value = NULL;
}
if (value == NULL)
c->metadata->default_audio_source[0] = '\0';
}
} else {
if ((o = find_id(c, id, true)) == NULL)
return -EINVAL;
switch (o->type) {
case INTERFACE_Node:
uuid = client_make_uuid(o->serial, false);
break;
case INTERFACE_Port:
uuid = jack_port_uuid_generate(o->serial);
break;
default:
return -EINVAL;
}
update_property(c, uuid, key, type, value);
}
return 0;
}
static const struct pw_metadata_events metadata_events = {
PW_VERSION_METADATA_EVENTS,
.property = metadata_property
};
static void metadata_proxy_removed(void *data)
{
struct client *c = data;
pw_proxy_destroy((struct pw_proxy*)c->metadata->proxy);
}
static void metadata_proxy_destroy(void *data)
{
struct client *c = data;
spa_hook_remove(&c->metadata->proxy_listener);
spa_hook_remove(&c->metadata->listener);
c->metadata = NULL;
}
static const struct pw_proxy_events metadata_proxy_events = {
PW_VERSION_PROXY_EVENTS,
.removed = metadata_proxy_removed,
.destroy = metadata_proxy_destroy,
};
static void settings_proxy_removed(void *data)
{
struct client *c = data;
pw_proxy_destroy((struct pw_proxy*)c->settings->proxy);
}
static void settings_proxy_destroy(void *data)
{
struct client *c = data;
spa_hook_remove(&c->settings->proxy_listener);
c->settings = NULL;
}
static const struct pw_proxy_events settings_proxy_events = {
PW_VERSION_PROXY_EVENTS,
.removed = settings_proxy_removed,
.destroy = settings_proxy_destroy,
};
static void proxy_removed(void *data)
{
struct object *o = data;
pw_proxy_destroy(o->proxy);
}
static void proxy_destroy(void *data)
{
struct object *o = data;
spa_hook_remove(&o->proxy_listener);
spa_hook_remove(&o->object_listener);
o->proxy = NULL;
}
static const struct pw_proxy_events proxy_events = {
PW_VERSION_PROXY_EVENTS,
.removed = proxy_removed,
.destroy = proxy_destroy,
};
static bool node_is_active(struct client *c, struct object *n)
{
return !n->node.is_jack ||
(c->node_id == n->id ? c->active : n->node.is_running);
}
static void node_info(void *data, const struct pw_node_info *info)
{
struct object *n = data;
struct client *c = n->client;
bool active;
if (info->change_mask & PW_NODE_CHANGE_MASK_PROPS) {
/* JACK clients always need ALWAYS_PROCESS=true or else they don't
* conform to the JACK API. We would try to hide the ports of
* PAUSED JACK clients, for example, even if they are active. */
const char *str = spa_dict_lookup(info->props, PW_KEY_NODE_ALWAYS_PROCESS);
n->node.is_jack = str ? spa_atob(str) : false;
}
n->node.is_running = info->state == PW_NODE_STATE_RUNNING;
active = node_is_active(c, n);
pw_log_debug("DSP node %d %08"PRIx64" jack:%u state change %s running:%d", info->id,
info->change_mask, n->node.is_jack,
pw_node_state_as_string(info->state), n->node.is_running);
if (info->change_mask & PW_NODE_CHANGE_MASK_STATE) {
struct object *p, *l;
spa_list_for_each(p, &c->context.objects, link) {
if (p->type != INTERFACE_Port || p->removed ||
p->port.node_id != info->id)
continue;
if (active)
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, p, 1, NULL);
else {
spa_list_for_each(l, &c->context.objects, link) {
if (l->type != INTERFACE_Link || l->removed ||
(l->port_link.src_serial != p->serial &&
l->port_link.dst_serial != p->serial))
continue;
queue_notify(c, NOTIFY_TYPE_CONNECT, l, 0, NULL);
}
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, p, 0, NULL);
}
}
}
}
static const struct pw_node_events node_events = {
PW_VERSION_NODE_EVENTS,
.info = node_info,
};
#define FILTER_NAME " ()[].:*$"
#define FILTER_PORT " ()[].*$"
static void filter_name(char *str, const char *filter, char filter_char)
{
char *p;
for (p = str; *p; p++) {
if (strchr(filter, *p) != NULL)
*p = filter_char;
}
}
static int update_port_name(struct object *o, const char *name)
{
struct object *ot = o->port.node, *op;
struct client *c = o->client;
char tmp[REAL_JACK_PORT_NAME_SIZE+1];
char port_name[REAL_JACK_PORT_NAME_SIZE+1];
if (o->port.is_monitor && !c->merge_monitor)
snprintf(tmp, sizeof(tmp), "%.*s%s:%s",
(int)(JACK_CLIENT_NAME_SIZE-(sizeof(MONITOR_EXT)-1)),
ot->node.name, MONITOR_EXT, name);
else
snprintf(tmp, sizeof(tmp), "%s:%s", ot->node.name, name);
if (c->filter_name)
filter_name(tmp, FILTER_PORT, c->filter_char);
op = find_port_by_name(c, tmp);
if (op != NULL && op != o)
snprintf(port_name, sizeof(port_name), "%.*s-%u",
(int)(sizeof(tmp)-11), tmp, o->serial);
else
snprintf(port_name, sizeof(port_name), "%s", tmp);
if (spa_streq(port_name, o->port.name))
return 0;
strcpy(o->port.old_name, o->port.name);
strcpy(o->port.name, port_name);
return 1;
}
static void port_info(void *data, const struct pw_port_info *info)
{
struct object *o = data;
struct client *c = o->client;
if (info->change_mask & PW_PORT_CHANGE_MASK_PROPS) {
const char *str = spa_dict_lookup(info->props, PW_KEY_PORT_NAME);
if (str != NULL) {
if (update_port_name(o, str) > 0) {
pw_log_info("%p: port rename %u %s->%s", c, o->serial,
o->port.old_name, o->port.name);
queue_notify(c, NOTIFY_TYPE_PORT_RENAME, o, 1, NULL);
}
}
}
}
static void port_param(void *data, int seq,
uint32_t id, uint32_t index, uint32_t next,
const struct spa_pod *param)
{
struct object *o = data;
switch (id) {
case SPA_PARAM_Latency:
{
struct spa_latency_info info;
if (spa_latency_parse(param, &info) < 0)
return;
o->port.latency[info.direction] = info;
break;
}
default:
break;
}
}
static const struct pw_port_events port_events = {
PW_VERSION_PORT_EVENTS,
.info = port_info,
.param = port_param,
};
static void registry_event_global(void *data, uint32_t id,
uint32_t permissions, const char *type, uint32_t version,
const struct spa_dict *props)
{
struct client *c = (struct client *) data;
struct object *o, *ot;
const char *str;
bool do_emit = true, do_sync = false;
uint32_t serial;
const char *app;
if (props == NULL)
return;
str = spa_dict_lookup(props, PW_KEY_OBJECT_SERIAL);
if (!spa_atou32(str, &serial, 0))
serial = SPA_ID_INVALID;
pw_log_debug("new %s id:%u serial:%u", type, id, serial);
if (spa_streq(type, PW_TYPE_INTERFACE_Client)) {
app = spa_dict_lookup(props, PW_KEY_APP_NAME);
if ((str = spa_dict_lookup(props, PW_KEY_SEC_PID)) != NULL) {
pw_log_debug("%p: pid of \"%s\" is \"%s\"", c, app, str);
} else {
pw_log_debug("%p: pid of \"%s\" is unknown", c, app);
}
o = alloc_object(c, INTERFACE_Client);
if (o == NULL)
goto exit;
o->pwclient.pid = (int32_t)atoi(str);
snprintf(o->pwclient.name, sizeof(o->pwclient.name), "%s", app);
pw_log_debug("%p: add pw client %d (%s) pid %llu", c, id, app, (unsigned long long)o->pwclient.pid);
pthread_mutex_lock(&c->context.lock);
spa_list_append(&c->context.objects, &o->link);
pthread_mutex_unlock(&c->context.lock);
}
else if (spa_streq(type, PW_TYPE_INTERFACE_Node)) {
const char *node_name;
char tmp[JACK_CLIENT_NAME_SIZE+1];
o = alloc_object(c, INTERFACE_Node);
if (o == NULL)
goto exit;
if ((str = spa_dict_lookup(props, PW_KEY_CLIENT_ID)) != NULL)
o->node.client_id = atoi(str);
node_name = spa_dict_lookup(props, PW_KEY_NODE_NAME);
snprintf(o->node.node_name, sizeof(o->node.node_name),
"%s", node_name);
app = spa_dict_lookup(props, PW_KEY_APP_NAME);
if (c->short_name) {
str = spa_dict_lookup(props, PW_KEY_NODE_NICK);
if (str == NULL)
str = spa_dict_lookup(props, PW_KEY_NODE_DESCRIPTION);
} else {
str = spa_dict_lookup(props, PW_KEY_NODE_DESCRIPTION);
if (str == NULL)
str = spa_dict_lookup(props, PW_KEY_NODE_NICK);
}
if (str == NULL)
str = node_name;
if (str == NULL)
str = spa_dict_lookup(props, PW_KEY_OBJECT_PATH);
if (str == NULL)
str = "node";
if (app && !spa_streq(app, str))
snprintf(tmp, sizeof(tmp), "%s/%s", app, str);
else
snprintf(tmp, sizeof(tmp), "%s", str);
if (c->filter_name)
filter_name(tmp, FILTER_NAME, c->filter_char);
ot = find_node(c, tmp);
if (ot != NULL && o->node.client_id != ot->node.client_id) {
snprintf(o->node.name, sizeof(o->node.name), "%.*s-%d",
(int)(sizeof(tmp)-11), tmp, id);
} else {
do_emit = ot == NULL;
snprintf(o->node.name, sizeof(o->node.name), "%s", tmp);
}
if (id == c->node_id) {
pw_log_debug("%p: add our node %d", c, id);
snprintf(c->name, sizeof(c->name), "%s", o->node.name);
c->object = o;
c->serial = serial;
}
if ((str = spa_dict_lookup(props, PW_KEY_PRIORITY_SESSION)) != NULL)
o->node.priority = pw_properties_parse_int(str);
if ((str = spa_dict_lookup(props, PW_KEY_CLIENT_API)) != NULL)
o->node.is_jack = spa_streq(str, "jack");
pw_log_debug("%p: add node %d", c, id);
if (o->node.is_jack) {
o->proxy = pw_registry_bind(c->registry,
id, type, PW_VERSION_NODE, 0);
if (o->proxy) {
pw_proxy_add_listener(o->proxy,
&o->proxy_listener, &proxy_events, o);
pw_proxy_add_object_listener(o->proxy,
&o->object_listener, &node_events, o);
do_sync = true;
}
}
pthread_mutex_lock(&c->context.lock);
spa_list_append(&c->context.objects, &o->link);
pthread_mutex_unlock(&c->context.lock);
}
else if (spa_streq(type, PW_TYPE_INTERFACE_Port)) {
const struct spa_dict_item *item;
unsigned long flags = 0;
jack_port_type_id_t type_id;
uint32_t node_id;
bool is_monitor = false;
char tmp[REAL_JACK_PORT_NAME_SIZE+1];
const char *name;
if ((str = spa_dict_lookup(props, PW_KEY_FORMAT_DSP)) == NULL)
str = "other";
if ((type_id = string_to_type(str)) == SPA_ID_INVALID)
goto exit;
if ((str = spa_dict_lookup(props, PW_KEY_NODE_ID)) == NULL)
goto exit;
node_id = atoi(str);
if ((str = spa_dict_lookup(props, PW_KEY_PORT_EXTRA)) != NULL &&
spa_strstartswith(str, "jack:flags:"))
flags = atoi(str+11);
if ((name = spa_dict_lookup(props, PW_KEY_PORT_NAME)) == NULL)
goto exit;
if (type_id == TYPE_ID_UMP && c->flag_midi2)
flags |= JackPortIsMIDI2;
spa_dict_for_each(item, props) {
if (spa_streq(item->key, PW_KEY_PORT_DIRECTION)) {
if (spa_streq(item->value, "in"))
flags |= JackPortIsInput;
else if (spa_streq(item->value, "out"))
flags |= JackPortIsOutput;
}
else if (spa_streq(item->key, PW_KEY_PORT_PHYSICAL)) {
if (pw_properties_parse_bool(item->value))
flags |= JackPortIsPhysical;
}
else if (spa_streq(item->key, PW_KEY_PORT_TERMINAL)) {
if (pw_properties_parse_bool(item->value))
flags |= JackPortIsTerminal;
}
else if (spa_streq(item->key, PW_KEY_PORT_CONTROL)) {
if (pw_properties_parse_bool(item->value))
type_id = TYPE_ID_MIDI;
}
else if (spa_streq(item->key, PW_KEY_PORT_MONITOR)) {
is_monitor = pw_properties_parse_bool(item->value);
}
}
if (is_monitor && !c->show_monitor)
goto exit;
if (TYPE_ID_IS_EVENT(type_id) && !c->show_midi)
goto exit;
o = NULL;
if (node_id == c->node_id) {
snprintf(tmp, sizeof(tmp), "%s:%s", c->name, name);
o = find_port_by_name(c, tmp);
if (o != NULL)
pw_log_info("%p: %s found our port %p", c, tmp, o);
}
if (o == NULL) {
if ((ot = find_type(c, node_id, INTERFACE_Node, true)) == NULL)
goto exit;
o = alloc_object(c, INTERFACE_Port);
if (o == NULL)
goto exit;
o->port.system_id = 0;
o->port.priority = ot->node.priority;
o->port.node = ot;
o->port.latency[SPA_DIRECTION_INPUT] = SPA_LATENCY_INFO(SPA_DIRECTION_INPUT);
o->port.latency[SPA_DIRECTION_OUTPUT] = SPA_LATENCY_INFO(SPA_DIRECTION_OUTPUT);
o->port.type_id = type_id;
do_emit = node_is_active(c, ot);
o->proxy = pw_registry_bind(c->registry,
id, type, PW_VERSION_PORT, 0);
if (o->proxy) {
uint32_t ids[1] = { SPA_PARAM_Latency };
pw_proxy_add_listener(o->proxy,
&o->proxy_listener, &proxy_events, o);
pw_proxy_add_object_listener(o->proxy,
&o->object_listener, &port_events, o);
if (type_is_dsp(type_id))
pw_port_subscribe_params((struct pw_port*)o->proxy,
ids, 1);
do_sync = true;
}
pthread_mutex_lock(&c->context.lock);
spa_list_append(&c->context.objects, &o->link);
pthread_mutex_unlock(&c->context.lock);
}
o->port.flags = flags;
o->port.node_id = node_id;
o->port.is_monitor = is_monitor;
if (c->fill_aliases) {
if ((str = spa_dict_lookup(props, PW_KEY_OBJECT_PATH)) != NULL)
snprintf(o->port.alias1, sizeof(o->port.alias1), "%s", str);
if ((str = spa_dict_lookup(props, PW_KEY_PORT_ALIAS)) != NULL)
snprintf(o->port.alias2, sizeof(o->port.alias2), "%s", str);
}
if ((str = spa_dict_lookup(props, PW_KEY_PORT_ID)) != NULL) {
o->port.system_id = atoi(str);
snprintf(o->port.system, sizeof(o->port.system), "system:%s_%d",
flags & JackPortIsInput ? "playback" :
is_monitor ? "monitor" : "capture",
o->port.system_id+1);
}
if (node_id != c->node_id)
update_port_name(o, name);
pw_log_debug("%p: %p add port %d name:%s %d", c, o, id,
o->port.name, type_id);
}
else if (spa_streq(type, PW_TYPE_INTERFACE_Link)) {
struct object *p;
o = alloc_object(c, INTERFACE_Link);
if (o == NULL)
goto exit;
pthread_mutex_lock(&c->context.lock);
spa_list_append(&c->context.objects, &o->link);
pthread_mutex_unlock(&c->context.lock);
if ((str = spa_dict_lookup(props, PW_KEY_LINK_OUTPUT_PORT)) == NULL)
goto exit_free;
o->port_link.src = pw_properties_parse_int(str);
if ((p = find_type(c, o->port_link.src, INTERFACE_Port, true)) == NULL)
goto exit_free;
o->port_link.src_serial = p->serial;
o->port_link.src_ours = p->port.port != NULL &&
p->port.port->client == c;
if (o->port_link.src_ours)
o->port_link.our_output = p->port.port;
if ((str = spa_dict_lookup(props, PW_KEY_LINK_INPUT_PORT)) == NULL)
goto exit_free;
o->port_link.dst = pw_properties_parse_int(str);
if ((p = find_type(c, o->port_link.dst, INTERFACE_Port, true)) == NULL)
goto exit_free;
o->port_link.dst_serial = p->serial;
o->port_link.dst_ours = p->port.port != NULL &&
p->port.port->client == c;
if (o->port_link.dst_ours)
o->port_link.our_input = p->port.port;
if (o->port_link.our_input != NULL &&
o->port_link.our_output != NULL) {
struct mix *mix;
mix = find_port_peer(o->port_link.our_output, o->port_link.dst);
if (mix != NULL)
mix->peer_port = o->port_link.our_input;
mix = find_port_peer(o->port_link.our_input, o->port_link.src);
if (mix != NULL)
mix->peer_port = o->port_link.our_output;
}
pw_log_debug("%p: add link %d %u/%u->%u/%u", c, id,
o->port_link.src, o->port_link.src_serial,
o->port_link.dst, o->port_link.dst_serial);
}
else if (spa_streq(type, PW_TYPE_INTERFACE_Metadata)) {
struct pw_proxy *proxy;
if (c->metadata != NULL)
goto exit;
if ((str = spa_dict_lookup(props, PW_KEY_METADATA_NAME)) == NULL)
goto exit;
if (spa_streq(str, "default")) {
proxy = pw_registry_bind(c->registry,
id, type, PW_VERSION_METADATA, sizeof(struct metadata));
c->metadata = pw_proxy_get_user_data(proxy);
c->metadata->proxy = (struct pw_metadata*)proxy;
c->metadata->default_audio_sink[0] = '\0';
c->metadata->default_audio_source[0] = '\0';
pw_proxy_add_listener(proxy,
&c->metadata->proxy_listener,
&metadata_proxy_events, c);
pw_metadata_add_listener(c->metadata->proxy,
&c->metadata->listener,
&metadata_events, c);
do_sync = true;
} else if (spa_streq(str, "settings")) {
proxy = pw_registry_bind(c->registry,
id, type, PW_VERSION_METADATA, sizeof(struct metadata));
c->settings = pw_proxy_get_user_data(proxy);
c->settings->proxy = (struct pw_metadata*)proxy;
pw_proxy_add_listener(proxy,
&c->settings->proxy_listener,
&settings_proxy_events, c);
do_sync = true;
}
goto exit;
}
else {
goto exit;
}
o->id = id;
o->serial = serial;
switch (o->type) {
case INTERFACE_Node:
pw_log_info("%p: client added \"%s\" emit:%d", c, o->node.name, do_emit);
if (do_emit)
queue_notify(c, NOTIFY_TYPE_REGISTRATION, o, 1, NULL);
break;
case INTERFACE_Port:
pw_log_info("%p: port added %u/%u \"%s\" emit:%d", c, o->id,
o->serial, o->port.name, do_emit);
if (do_emit)
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, o, 1, NULL);
break;
case INTERFACE_Link:
pw_log_info("%p: link %u %u/%u -> %u/%u added", c,
o->id, o->port_link.src, o->port_link.src_serial,
o->port_link.dst, o->port_link.dst_serial);
if (do_emit)
queue_notify(c, NOTIFY_TYPE_CONNECT, o, 1, NULL);
break;
}
exit:
if (do_sync)
c->pending_sync = pw_proxy_sync((struct pw_proxy*)c->core,
c->pending_sync);
return;
exit_free:
free_object(c, o);
return;
}
static void registry_event_global_remove(void *data, uint32_t id)
{
struct client *c = (struct client *) data;
struct object *o;
pw_log_debug("%p: removed: %u", c, id);
if ((o = find_id(c, id, true)) == NULL)
return;
if (o->proxy) {
pw_proxy_destroy(o->proxy);
o->proxy = NULL;
}
o->removing = true;
switch (o->type) {
case INTERFACE_Client:
free_object(c, o);
break;
case INTERFACE_Node:
if (c->metadata) {
if (spa_streq(o->node.node_name, c->metadata->default_audio_sink))
c->metadata->default_audio_sink[0] = '\0';
if (spa_streq(o->node.node_name, c->metadata->default_audio_source))
c->metadata->default_audio_source[0] = '\0';
}
if (find_node(c, o->node.name) == NULL) {
pw_log_info("%p: client %u removed \"%s\"", c, o->id, o->node.name);
queue_notify(c, NOTIFY_TYPE_REGISTRATION, o, 0, NULL);
} else {
free_object(c, o);
}
break;
case INTERFACE_Port:
pw_log_info("%p: port %u/%u removed \"%s\"", c, o->id, o->serial, o->port.name);
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, o, 0, NULL);
break;
case INTERFACE_Link:
if (find_type(c, o->port_link.src, INTERFACE_Port, true) != NULL &&
find_type(c, o->port_link.dst, INTERFACE_Port, true) != NULL) {
pw_log_info("%p: link %u %u/%u -> %u/%u removed", c, o->id,
o->port_link.src, o->port_link.src_serial,
o->port_link.dst, o->port_link.dst_serial);
queue_notify(c, NOTIFY_TYPE_CONNECT, o, 0, NULL);
} else {
pw_log_warn("unlink between unknown ports %d and %d",
o->port_link.src, o->port_link.dst);
free_object(c, o);
}
break;
}
return;
}
static const struct pw_registry_events registry_events = {
PW_VERSION_REGISTRY_EVENTS,
.global = registry_event_global,
.global_remove = registry_event_global_remove,
};
static void varargs_parse (struct client *c, jack_options_t options, va_list ap)
{
if ((options & JackServerName))
c->server_name = va_arg(ap, char *);
if ((options & JackLoadName))
c->load_name = va_arg(ap, char *);
if ((options & JackLoadInit))
c->load_init = va_arg(ap, char *);
if ((options & JackSessionID)) {
char *sid = va_arg(ap, char *);
if (sid) {
const long long id = atoll(sid);
if (id > 0)
c->session_id = id;
}
}
}
static int execute_match(void *data, const char *location, const char *action,
const char *val, size_t len)
{
struct client *client = data;
if (spa_streq(action, "update-props"))
pw_properties_update_string(client->props, val, len);
return 1;
}
static struct client * g_first_client;
SPA_EXPORT
jack_client_t * jack_client_open (const char *client_name,
jack_options_t options,
jack_status_t *status_ptr, ...)
{
struct client *client;
const struct spa_support *support;
uint32_t n_support;
const char *str;
struct spa_cpu *cpu_iface;
const struct pw_properties *props;
va_list ap;
jack_status_t status;
if (getenv("PIPEWIRE_NOJACK") != NULL ||
getenv("PIPEWIRE_INTERNAL") != NULL ||
spa_strstartswith(pw_get_library_version(), "0.2"))
goto disabled;
return_val_if_fail(client_name != NULL, NULL);
client = calloc(1, sizeof(struct client));
if (client == NULL)
goto disabled;
pw_log_info("%p: open '%s' options:%d", client, client_name, options);
va_start(ap, status_ptr);
varargs_parse(client, options, ap);
va_end(ap);
snprintf(client->name, sizeof(client->name), "pw-%s", client_name);
pthread_mutex_init(&client->context.lock, NULL);
spa_list_init(&client->context.objects);
client->node_id = SPA_ID_INVALID;
client->buffer_frames = (uint32_t)-1;
client->sample_rate = (uint32_t)-1;
client->latency = SPA_FRACTION(-1, -1);
spa_list_init(&client->mix);
spa_list_init(&client->free_mix);
spa_list_init(&client->free_ports);
pw_map_init(&client->ports[SPA_DIRECTION_INPUT], 32, 32);
pw_map_init(&client->ports[SPA_DIRECTION_OUTPUT], 32, 32);
spa_list_init(&client->links);
client->driver_id = SPA_ID_INVALID;
spa_list_init(&client->rt.target_links);
pthread_mutex_init(&client->rt_lock, NULL);
if (client->server_name != NULL &&
spa_streq(client->server_name, "default"))
client->server_name = NULL;
client->props = pw_properties_new(
PW_KEY_LOOP_CANCEL, "true",
PW_KEY_REMOTE_NAME, client->server_name,
PW_KEY_CLIENT_NAME, client_name,
PW_KEY_CLIENT_API, "jack",
PW_KEY_CONFIG_NAME, "jack.conf",
NULL);
if (client->props == NULL)
goto no_props;
client->context.loop = pw_thread_loop_new(client->name, NULL);
if (client->context.loop == NULL)
goto no_props;
client->context.l = pw_thread_loop_get_loop(client->context.loop);
client->context.context = pw_context_new(
client->context.l,
pw_properties_copy(client->props),
0);
if (client->context.context == NULL)
goto no_props;
client->context.notify = pw_thread_loop_new(client->name, NULL);
if (client->context.notify == NULL)
goto no_props;
client->context.nl = pw_thread_loop_get_loop(client->context.notify);
globals.max_frames = client->max_frames = client->context.context->settings.clock_quantum_limit;
client->notify_source = pw_loop_add_event(client->context.nl,
on_notify_event, client);
client->notify_buffer = calloc(1, NOTIFY_BUFFER_SIZE + sizeof(struct notify));
spa_ringbuffer_init(&client->notify_ring);
pw_context_conf_update_props(client->context.context,
"jack.properties", client->props);
props = pw_context_get_properties(client->context.context);
client->allow_mlock = pw_properties_get_bool(props, "mem.allow-mlock", true);
client->warn_mlock = pw_properties_get_bool(props, "mem.warn-mlock", false);
pw_context_conf_section_match_rules(client->context.context, "jack.rules",
&props->dict, execute_match, client);
support = pw_context_get_support(client->context.context, &n_support);
client->mix_function = mix_c;
cpu_iface = spa_support_find(support, n_support, SPA_TYPE_INTERFACE_CPU);
if (cpu_iface) {
#if defined (__SSE__)
uint32_t flags = spa_cpu_get_flags(cpu_iface);
if (flags & SPA_CPU_FLAG_SSE)
client->mix_function = mix_sse;
#endif
client->max_align = spa_cpu_get_max_align(cpu_iface);
} else {
client->max_align = MAX_ALIGN;
}
client->context.old_thread_utils =
pw_context_get_object(client->context.context,
SPA_TYPE_INTERFACE_ThreadUtils);
if (client->context.old_thread_utils == NULL)
client->context.old_thread_utils = pw_thread_utils_get();
globals.thread_utils = client->context.old_thread_utils;
client->context.thread_utils.iface = SPA_INTERFACE_INIT(
SPA_TYPE_INTERFACE_ThreadUtils,
SPA_VERSION_THREAD_UTILS,
&thread_utils_impl, client);
client->loop = pw_context_get_data_loop(client->context.context);
client->l = pw_data_loop_get_loop(client->loop);
pw_data_loop_stop(client->loop);
pw_context_set_object(client->context.context,
SPA_TYPE_INTERFACE_ThreadUtils,
&client->context.thread_utils);
pw_thread_loop_start(client->context.loop);
pw_thread_loop_lock(client->context.loop);
client->core = pw_context_connect(client->context.context,
pw_properties_copy(client->props), 0);
if (client->core == NULL)
goto server_failed;
client->pool = pw_core_get_mempool(client->core);
pw_core_add_listener(client->core,
&client->core_listener,
&core_events, client);
client->registry = pw_core_get_registry(client->core,
PW_VERSION_REGISTRY, 0);
pw_registry_add_listener(client->registry,
&client->registry_listener,
&registry_events, client);
if ((str = getenv("PIPEWIRE_PROPS")) != NULL)
pw_properties_update_string(client->props, str, strlen(str));
if ((str = getenv("PIPEWIRE_QUANTUM")) != NULL) {
struct spa_fraction q;
if (sscanf(str, "%u/%u", &q.num, &q.denom) == 2 && q.denom != 0) {
pw_properties_setf(client->props, PW_KEY_NODE_FORCE_RATE,
"%u", q.denom);
pw_properties_setf(client->props, PW_KEY_NODE_FORCE_QUANTUM,
"%u", q.num);
} else {
pw_log_warn("invalid PIPEWIRE_QUANTUM: %s", str);
}
}
if ((str = getenv("PIPEWIRE_LATENCY")) != NULL)
pw_properties_set(client->props, PW_KEY_NODE_LATENCY, str);
if ((str = getenv("PIPEWIRE_RATE")) != NULL)
pw_properties_set(client->props, PW_KEY_NODE_RATE, str);
if ((str = getenv("PIPEWIRE_LINK_PASSIVE")) != NULL)
pw_properties_set(client->props, "jack.passive-links", str);
if ((str = pw_properties_get(client->props, PW_KEY_NODE_LATENCY)) != NULL) {
uint32_t num, denom;
if (sscanf(str, "%u/%u", &num, &denom) == 2 && denom != 0) {
client->latency = SPA_FRACTION(num, denom);
}
}
if (pw_properties_get(client->props, PW_KEY_NODE_NAME) == NULL)
pw_properties_set(client->props, PW_KEY_NODE_NAME, client_name);
if (pw_properties_get(client->props, PW_KEY_NODE_GROUP) == NULL)
pw_properties_setf(client->props, PW_KEY_NODE_GROUP, "group.dsp.0");
if (pw_properties_get(client->props, PW_KEY_NODE_DESCRIPTION) == NULL)
pw_properties_set(client->props, PW_KEY_NODE_DESCRIPTION, client_name);
if (pw_properties_get(client->props, PW_KEY_MEDIA_TYPE) == NULL)
pw_properties_set(client->props, PW_KEY_MEDIA_TYPE, "Audio");
if (pw_properties_get(client->props, PW_KEY_MEDIA_CATEGORY) == NULL)
pw_properties_set(client->props, PW_KEY_MEDIA_CATEGORY, "Duplex");
if (pw_properties_get(client->props, PW_KEY_MEDIA_ROLE) == NULL)
pw_properties_set(client->props, PW_KEY_MEDIA_ROLE, "DSP");
if (pw_properties_get(client->props, PW_KEY_NODE_ALWAYS_PROCESS) == NULL)
pw_properties_set(client->props, PW_KEY_NODE_ALWAYS_PROCESS, "true");
if (pw_properties_get(client->props, PW_KEY_NODE_LOCK_QUANTUM) == NULL)
pw_properties_set(client->props, PW_KEY_NODE_LOCK_QUANTUM, "true");
pw_properties_set(client->props, PW_KEY_NODE_TRANSPORT_SYNC, "true");
client->node = pw_core_create_object(client->core,
"client-node",
PW_TYPE_INTERFACE_ClientNode,
PW_VERSION_CLIENT_NODE,
&client->props->dict,
0);
if (client->node == NULL)
goto init_failed;
pw_client_node_add_listener(client->node,
&client->node_listener, &client_node_events, client);
pw_proxy_add_listener((struct pw_proxy*)client->node,
&client->proxy_listener, &node_proxy_events, client);
client->info = SPA_NODE_INFO_INIT();
client->info.max_input_ports = UINT32_MAX;
client->info.max_output_ports = UINT32_MAX;
client->info.change_mask = SPA_NODE_CHANGE_MASK_FLAGS |
SPA_NODE_CHANGE_MASK_PROPS;
client->info.flags = SPA_NODE_FLAG_RT;
client->info.props = &client->props->dict;
pw_client_node_update(client->node,
PW_CLIENT_NODE_UPDATE_INFO,
0, NULL, &client->info);
client->info.change_mask = 0;
client->show_monitor = pw_properties_get_bool(client->props, "jack.show-monitor", true);
client->show_midi = pw_properties_get_bool(client->props, "jack.show-midi", true);
client->merge_monitor = pw_properties_get_bool(client->props, "jack.merge-monitor", true);
client->short_name = pw_properties_get_bool(client->props, "jack.short-name", false);
client->filter_name = pw_properties_get_bool(client->props, "jack.filter-name", false);
client->passive_links = pw_properties_get_bool(client->props, "jack.passive-links", false);
client->filter_char = ' ';
if ((str = pw_properties_get(client->props, "jack.filter-char")) != NULL && str[0] != '\0')
client->filter_char = str[0];
client->locked_process = pw_properties_get_bool(client->props, "jack.locked-process", true);
client->default_as_system = pw_properties_get_bool(client->props, "jack.default-as-system", false);
client->fix_midi_events = pw_properties_get_bool(client->props, "jack.fix-midi-events", true);
client->global_buffer_size = pw_properties_get_bool(client->props, "jack.global-buffer-size", false);
client->global_sample_rate = pw_properties_get_bool(client->props, "jack.global-sample-rate", false);
client->max_ports = pw_properties_get_uint32(client->props, "jack.max-client-ports", MAX_CLIENT_PORTS);
client->fill_aliases = pw_properties_get_bool(client->props, "jack.fill-aliases", false);
client->writable_input = pw_properties_get_bool(client->props, "jack.writable-input", true);
client->async = pw_properties_get_bool(client->props, PW_KEY_NODE_ASYNC, false);
client->flag_midi2 = pw_properties_get_bool(client->props, "jack.flag-midi2", false);
client->self_connect_mode = SELF_CONNECT_ALLOW;
if ((str = pw_properties_get(client->props, "jack.self-connect-mode")) != NULL) {
if (spa_streq(str, "fail-external"))
client->self_connect_mode = SELF_CONNECT_FAIL_EXT;
else if (spa_streq(str, "ignore-external"))
client->self_connect_mode = SELF_CONNECT_IGNORE_EXT;
else if (spa_streq(str, "fail-all"))
client->self_connect_mode = SELF_CONNECT_FAIL_ALL;
else if (spa_streq(str, "ignore-all"))
client->self_connect_mode = SELF_CONNECT_IGNORE_ALL;
}
client->other_connect_mode = OTHER_CONNECT_ALLOW;
if ((str = pw_properties_get(client->props, "jack.other-connect-mode")) != NULL) {
if (spa_streq(str, "fail"))
client->other_connect_mode = OTHER_CONNECT_FAIL;
else if (spa_streq(str, "ignore"))
client->other_connect_mode = OTHER_CONNECT_IGNORE;
}
client->rt_max = pw_properties_get_int32(client->props, "rt.prio", DEFAULT_RT_MAX);
status = 0;
if (status_ptr)
*status_ptr = status;
client->pending_sync = pw_proxy_sync((struct pw_proxy*)client->core, client->pending_sync);
while (true) {
pw_thread_loop_wait(client->context.loop);
if (client->last_res < 0)
goto init_failed;
if (client->pending_sync == client->last_sync)
break;
}
if (!spa_streq(client->name, client_name)) {
status |= JackNameNotUnique;
if (status_ptr)
*status_ptr = status;
if (options & JackUseExactName)
goto exit_unlock;
}
pw_thread_loop_unlock(client->context.loop);
if (g_first_client == NULL)
g_first_client = client;
pw_thread_loop_start(client->context.notify);
pw_log_info("%p: opened", client);
return (jack_client_t *)client;
no_props:
status = JackFailure | JackInitFailure;
if (status_ptr)
*status_ptr = status;
goto exit;
init_failed:
status = JackFailure | JackInitFailure;
if (status_ptr)
*status_ptr = status;
goto exit_unlock;
server_failed:
status = JackFailure | JackServerFailed;
if (status_ptr)
*status_ptr = status;
goto exit_unlock;
exit_unlock:
pw_thread_loop_unlock(client->context.loop);
exit:
pw_log_info("%p: error %d", client, status);
jack_client_close((jack_client_t *) client);
return NULL;
disabled:
pw_log_warn("JACK is disabled");
status = JackFailure | JackInitFailure;
if (status_ptr)
*status_ptr = status;
return NULL;
}
SPA_EXPORT
jack_client_t * jack_client_new (const char *client_name)
{
jack_options_t options = JackUseExactName;
jack_status_t status;
if (getenv("JACK_START_SERVER") == NULL)
options |= JackNoStartServer;
return jack_client_open(client_name, options, &status, NULL);
}
SPA_EXPORT
int jack_client_close (jack_client_t *client)
{
struct client *c = (struct client *) client;
struct object *o;
union pw_map_item *item;
struct mix *m, *tm;
struct port *p, *tp;
int res;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_info("%p: close", client);
if (g_first_client == c)
g_first_client = NULL;
c->destroyed = true;
res = jack_deactivate(client);
clean_transport(c);
if (c->context.loop) {
pw_loop_invoke(c->context.l, NULL, 0, NULL, 0, false, c);
pw_thread_loop_stop(c->context.loop);
}
if (c->context.notify) {
queue_notify(c, NOTIFY_TYPE_REGISTRATION, c->object, 0, NULL);
pw_loop_invoke(c->context.nl, NULL, 0, NULL, 0, false, c);
pw_thread_loop_stop(c->context.notify);
}
if (c->registry) {
spa_hook_remove(&c->registry_listener);
pw_proxy_destroy((struct pw_proxy*)c->registry);
}
if (c->metadata && c->metadata->proxy) {
pw_proxy_destroy((struct pw_proxy*)c->metadata->proxy);
}
if (c->settings && c->settings->proxy) {
pw_proxy_destroy((struct pw_proxy*)c->settings->proxy);
}
if (c->core) {
spa_hook_remove(&c->core_listener);
pw_core_disconnect(c->core);
}
globals.thread_utils = pw_thread_utils_get();
if (c->context.context)
pw_context_destroy(c->context.context);
if (c->notify_source)
pw_loop_destroy_source(c->context.nl, c->notify_source);
free(c->notify_buffer);
if (c->context.loop)
pw_thread_loop_destroy(c->context.loop);
if (c->context.notify)
pw_thread_loop_destroy(c->context.notify);
pw_log_debug("%p: free", client);
pw_array_for_each(item, &c->ports[SPA_DIRECTION_OUTPUT].items) {
if (pw_map_item_is_free(item))
continue;
free_port(c, item->data, false);
}
pw_array_for_each(item, &c->ports[SPA_DIRECTION_INPUT].items) {
if (pw_map_item_is_free(item))
continue;
free_port(c, item->data, false);
}
pthread_mutex_lock(&globals.lock);
spa_list_consume(o, &c->context.objects, link) {
bool to_free = o->to_free;
spa_list_remove(&o->link);
memset(o, 0, sizeof(struct object));
o->to_free = to_free;
spa_list_append(&globals.free_objects, &o->link);
}
pthread_mutex_unlock(&globals.lock);
spa_list_for_each_safe(m, tm, &c->free_mix, link) {
if (!m->to_free)
spa_list_remove(&m->link);
}
spa_list_consume(m, &c->free_mix, link) {
spa_list_remove(&m->link);
free(m);
}
spa_list_for_each_safe(p, tp, &c->free_ports, link) {
if (!p->to_free)
spa_list_remove(&p->link);
}
spa_list_consume(p, &c->free_ports, link) {
spa_list_remove(&p->link);
free(p);
}
pw_map_clear(&c->ports[SPA_DIRECTION_INPUT]);
pw_map_clear(&c->ports[SPA_DIRECTION_OUTPUT]);
pthread_mutex_destroy(&c->context.lock);
pthread_mutex_destroy(&c->rt_lock);
pw_properties_free(c->props);
free(c);
return res;
}
SPA_EXPORT
jack_intclient_t jack_internal_client_handle (jack_client_t *client,
const char *client_name, jack_status_t *status)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, 0);
if (status)
*status = JackNoSuchClient | JackFailure;
return 0;
}
SPA_EXPORT
jack_intclient_t jack_internal_client_load (jack_client_t *client,
const char *client_name, jack_options_t options,
jack_status_t *status, ...)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, 0);
if (status)
*status = JackNoSuchClient | JackFailure;
return 0;
}
SPA_EXPORT
jack_status_t jack_internal_client_unload (jack_client_t *client,
jack_intclient_t intclient)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, 0);
return JackFailure | JackNoSuchClient;
}
SPA_EXPORT
char *jack_get_internal_client_name (jack_client_t *client,
jack_intclient_t intclient)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, NULL);
return strdup(c->name);
}
SPA_EXPORT
int jack_client_name_size (void)
{
/* The JACK API specifies that this value includes the final NULL character. */
pw_log_trace("%d", JACK_CLIENT_NAME_SIZE+1);
return JACK_CLIENT_NAME_SIZE+1;
}
SPA_EXPORT
char * jack_get_client_name (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, NULL);
return c->name;
}
SPA_EXPORT
char *jack_get_uuid_for_client_name (jack_client_t *client,
const char *client_name)
{
struct client *c = (struct client *) client;
struct object *o;
char *uuid = NULL;
bool monitor;
return_val_if_fail(c != NULL, NULL);
return_val_if_fail(client_name != NULL, NULL);
monitor = spa_strendswith(client_name, MONITOR_EXT);
pthread_mutex_lock(&c->context.lock);
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Node)
continue;
if (spa_streq(o->node.name, client_name) ||
(monitor && spa_strneq(o->node.name, client_name,
strlen(client_name) - strlen(MONITOR_EXT)))) {
uuid = spa_aprintf( "%" PRIu64, client_make_uuid(o->serial, monitor));
break;
}
}
pw_log_debug("%p: name %s -> %s", client, client_name, uuid);
pthread_mutex_unlock(&c->context.lock);
return uuid;
}
SPA_EXPORT
char *jack_get_client_name_by_uuid (jack_client_t *client,
const char *client_uuid )
{
struct client *c = (struct client *) client;
struct object *o;
jack_uuid_t uuid;
char *name = NULL;
bool monitor;
return_val_if_fail(c != NULL, NULL);
return_val_if_fail(client_uuid != NULL, NULL);
if (jack_uuid_parse(client_uuid, &uuid) < 0)
return NULL;
monitor = uuid & (1 << 30);
pthread_mutex_lock(&c->context.lock);
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Node)
continue;
if (client_make_uuid(o->serial, monitor) == uuid) {
pw_log_debug("%p: uuid %s (%"PRIu64")-> %s",
client, client_uuid, uuid, o->node.name);
name = spa_aprintf("%s%s", o->node.name, monitor ? MONITOR_EXT : "");
break;
}
}
pthread_mutex_unlock(&c->context.lock);
return name;
}
SPA_EXPORT
int jack_internal_client_new (const char *client_name,
const char *load_name,
const char *load_init)
{
pw_log_warn("not implemented %s %s %s", client_name, load_name, load_init);
return -ENOTSUP;
}
SPA_EXPORT
void jack_internal_client_close (const char *client_name)
{
pw_log_warn("not implemented %s", client_name);
}
static int do_activate(struct client *c)
{
int res;
pw_client_node_set_active(c->node, true);
res = do_sync(c);
return res;
}
static int
do_emit_buffer_size(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct client *c = user_data;
c->buffer_frames = c->rt.position->clock.duration;
pw_log_debug("%p: emit buffersize %d", c, c->buffer_frames);
c->bufsize_callback(c->buffer_frames, c->bufsize_arg);
return 0;
}
SPA_EXPORT
int jack_activate (jack_client_t *client)
{
struct client *c = (struct client *) client;
struct object *o;
int res = 0;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_info("%p: active:%d", c, c->active);
if (c->active)
return 0;
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
/* reemit buffer_frames */
c->buffer_frames = 0;
pw_data_loop_start(c->loop);
c->active = true;
if ((res = do_activate(c)) < 0)
goto done;
c->activation->pending_new_pos = true;
c->activation->pending_sync = true;
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Port || o->port.port == NULL ||
o->port.port->client != c || !o->port.port->valid)
continue;
o->registered = 0;
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, o, 1, NULL);
}
done:
if (res < 0) {
c->active = false;
pw_data_loop_stop(c->loop);
} else if (SPA_LIKELY(c->bufsize_callback != NULL)) {
pw_thread_loop_unlock(c->context.loop);
pw_data_loop_invoke(c->loop,
do_emit_buffer_size, SPA_ID_INVALID, NULL, 0, true, c);
pw_thread_loop_lock(c->context.loop);
}
pw_log_debug("%p: activate result:%d", c, res);
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_deactivate (jack_client_t *client)
{
struct object *o;
struct client *c = (struct client *) client;
int res;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_info("%p: active:%d", c, c->active);
if (!c->active)
return 0;
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
pw_data_loop_stop(c->loop);
pw_client_node_set_active(c->node, false);
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Link || o->removed)
continue;
if (o->port_link.src_ours || o->port_link.dst_ours)
pw_registry_destroy(c->registry, o->id);
}
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Port || o->port.port == NULL ||
o->port.port->client != c || !o->port.port->valid)
continue;
queue_notify(c, NOTIFY_TYPE_PORTREGISTRATION, o, 0, NULL);
}
c->activation->pending_new_pos = false;
c->activation->pending_sync = false;
c->active = false;
res = do_sync(c);
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_get_client_pid (const char *name)
{
struct object *on, *oc;
if (g_first_client == NULL) return 0;
on = find_node(g_first_client, name);
if (on == NULL) {
pw_log_warn("unknown (jack-client) node \"%s\"", name);
return 0;
}
oc = find_client(g_first_client, on->node.client_id);
if (oc == NULL) {
pw_log_warn("unknown (pw) client %d", (int)on->node.client_id);
return 0;
}
pw_log_info("pid %d (%s)", (int)oc->pwclient.pid, oc->pwclient.name);
return (int)oc->pwclient.pid;
}
SPA_EXPORT
jack_native_thread_t jack_client_thread_id (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, (pthread_t){0});
return (jack_native_thread_t)pw_data_loop_get_thread(c->loop);
}
SPA_EXPORT
int jack_is_realtime (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, 0);
return !c->freewheeling;
}
SPA_EXPORT
jack_nframes_t jack_thread_wait (jack_client_t *client, int status)
{
pw_log_error("%p: jack_thread_wait: deprecated, use jack_cycle_wait/jack_cycle_signal", client);
return 0;
}
SPA_EXPORT
jack_nframes_t jack_cycle_wait (jack_client_t* client)
{
struct client *c = (struct client *) client;
jack_nframes_t res;
return_val_if_fail(c != NULL, 0);
res = cycle_wait(c);
pw_log_trace("%p: result:%d", c, res);
return res;
}
SPA_EXPORT
void jack_cycle_signal (jack_client_t* client, int status)
{
struct client *c = (struct client *) client;
return_if_fail(c != NULL);
pw_log_trace("%p: status:%d", c, status);
cycle_signal(c, status);
}
SPA_EXPORT
int jack_set_process_thread(jack_client_t* client, JackThreadCallback thread_callback, void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
} else if (c->process_callback) {
pw_log_error("%p: process callback was already set", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, thread_callback, arg);
c->thread_callback = thread_callback;
c->thread_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_thread_init_callback (jack_client_t *client,
JackThreadInitCallback thread_init_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_debug("%p: %p %p", c, thread_init_callback, arg);
c->thread_init_callback = thread_init_callback;
c->thread_init_arg = arg;
return 0;
}
SPA_EXPORT
void jack_on_shutdown (jack_client_t *client,
JackShutdownCallback shutdown_callback, void *arg)
{
struct client *c = (struct client *) client;
return_if_fail(c != NULL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
} else {
pw_log_debug("%p: %p %p", c, shutdown_callback, arg);
c->shutdown_callback = shutdown_callback;
c->shutdown_arg = arg;
}
}
SPA_EXPORT
void jack_on_info_shutdown (jack_client_t *client,
JackInfoShutdownCallback shutdown_callback, void *arg)
{
struct client *c = (struct client *) client;
return_if_fail(c != NULL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
} else {
pw_log_debug("%p: %p %p", c, shutdown_callback, arg);
c->info_shutdown_callback = shutdown_callback;
c->info_shutdown_arg = arg;
}
}
SPA_EXPORT
int jack_set_process_callback (jack_client_t *client,
JackProcessCallback process_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
} else if (c->thread_callback) {
pw_log_error("%p: thread callback was already set", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, process_callback, arg);
c->process_callback = process_callback;
c->process_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_freewheel_callback (jack_client_t *client,
JackFreewheelCallback freewheel_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, freewheel_callback, arg);
c->freewheel_callback = freewheel_callback;
c->freewheel_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_buffer_size_callback (jack_client_t *client,
JackBufferSizeCallback bufsize_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, bufsize_callback, arg);
c->bufsize_callback = bufsize_callback;
c->bufsize_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_sample_rate_callback (jack_client_t *client,
JackSampleRateCallback srate_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, srate_callback, arg);
c->srate_callback = srate_callback;
c->srate_arg = arg;
if (c->srate_callback && c->sample_rate != (uint32_t)-1)
c->srate_callback(c->sample_rate, c->srate_arg);
return 0;
}
SPA_EXPORT
int jack_set_client_registration_callback (jack_client_t *client,
JackClientRegistrationCallback
registration_callback, void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, registration_callback, arg);
c->registration_callback = registration_callback;
c->registration_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_port_registration_callback (jack_client_t *client,
JackPortRegistrationCallback
registration_callback, void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, registration_callback, arg);
c->portregistration_callback = registration_callback;
c->portregistration_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_port_connect_callback (jack_client_t *client,
JackPortConnectCallback
connect_callback, void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, connect_callback, arg);
c->connect_callback = connect_callback;
c->connect_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_port_rename_callback (jack_client_t *client,
JackPortRenameCallback rename_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, rename_callback, arg);
c->rename_callback = rename_callback;
c->rename_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_graph_order_callback (jack_client_t *client,
JackGraphOrderCallback graph_callback,
void *data)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, graph_callback, data);
c->graph_callback = graph_callback;
c->graph_arg = data;
return 0;
}
SPA_EXPORT
int jack_set_xrun_callback (jack_client_t *client,
JackXRunCallback xrun_callback, void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, xrun_callback, arg);
c->xrun_callback = xrun_callback;
c->xrun_arg = arg;
return 0;
}
SPA_EXPORT
int jack_set_latency_callback (jack_client_t *client,
JackLatencyCallback latency_callback,
void *data)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_debug("%p: %p %p", c, latency_callback, data);
c->latency_callback = latency_callback;
c->latency_arg = data;
return 0;
}
SPA_EXPORT
int jack_set_freewheel(jack_client_t* client, int onoff)
{
struct client *c = (struct client *) client;
const char *str;
pw_log_info("%p: freewheel %d", client, onoff);
pw_thread_loop_lock(c->context.loop);
str = pw_properties_get(c->props, PW_KEY_NODE_GROUP);
if (str != NULL) {
char *p = strstr(str, ",pipewire.freewheel");
if (p == NULL)
p = strstr(str, "pipewire.freewheel");
if (p == NULL && onoff)
pw_properties_setf(c->props, PW_KEY_NODE_GROUP,
"%s,pipewire.freewheel", str);
else if (p != NULL && !onoff) {
pw_log_info("%s %d %s %.*s", p, (int)(p - str),
str, (int)(p - str), str);
pw_properties_setf(c->props, PW_KEY_NODE_GROUP,
"%.*s", (int)(p - str), str);
}
} else {
pw_properties_set(c->props, PW_KEY_NODE_GROUP,
onoff ? "pipewire.freewheel" : "");
}
c->info.change_mask |= SPA_NODE_CHANGE_MASK_PROPS;
c->info.props = &c->props->dict;
pw_client_node_update(c->node,
PW_CLIENT_NODE_UPDATE_INFO,
0, NULL, &c->info);
c->info.change_mask = 0;
pw_thread_loop_unlock(c->context.loop);
return 0;
}
SPA_EXPORT
int jack_set_buffer_size (jack_client_t *client, jack_nframes_t nframes)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_info("%p: buffer-size %u", client, nframes);
pw_thread_loop_lock(c->context.loop);
if (c->global_buffer_size && c->settings && c->settings->proxy) {
char val[256];
snprintf(val, sizeof(val), "%u", nframes == 1 ? 0: nframes);
pw_metadata_set_property(c->settings->proxy, 0,
"clock.force-quantum", "", val);
} else {
pw_properties_setf(c->props, PW_KEY_NODE_FORCE_QUANTUM, "%u", nframes);
c->info.change_mask |= SPA_NODE_CHANGE_MASK_PROPS;
c->info.props = &c->props->dict;
pw_client_node_update(c->node,
PW_CLIENT_NODE_UPDATE_INFO,
0, NULL, &c->info);
c->info.change_mask = 0;
}
pw_thread_loop_unlock(c->context.loop);
return 0;
}
SPA_EXPORT
int jack_set_sample_rate (jack_client_t *client, jack_nframes_t nframes)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
pw_log_info("%p: sample-size %u", client, nframes);
pw_thread_loop_lock(c->context.loop);
if (c->global_sample_rate && c->settings && c->settings->proxy) {
char val[256];
snprintf(val, sizeof(val), "%u", nframes);
pw_metadata_set_property(c->settings->proxy, 0,
"clock.force-rate", "", val);
} else {
pw_properties_setf(c->props, PW_KEY_NODE_FORCE_RATE, "%u", nframes);
c->info.change_mask |= SPA_NODE_CHANGE_MASK_PROPS;
c->info.props = &c->props->dict;
pw_client_node_update(c->node,
PW_CLIENT_NODE_UPDATE_INFO,
0, NULL, &c->info);
c->info.change_mask = 0;
}
pw_thread_loop_unlock(c->context.loop);
return 0;
}
SPA_EXPORT
jack_nframes_t jack_get_sample_rate (jack_client_t *client)
{
struct client *c = (struct client *) client;
jack_nframes_t res = -1;
return_val_if_fail(c != NULL, 0);
if (!c->active)
res = c->latency.denom;
if (c->active || res == (uint32_t)-1) {
res = c->sample_rate;
if (res == (uint32_t)-1) {
if (c->rt.position)
res = c->rt.position->clock.rate.denom;
else if (c->position)
res = c->position->clock.rate.denom;
}
}
c->sample_rate = res;
pw_log_trace_fp("sample_rate: %u", res);
return res;
}
SPA_EXPORT
jack_nframes_t jack_get_buffer_size (jack_client_t *client)
{
struct client *c = (struct client *) client;
jack_nframes_t res = -1;
return_val_if_fail(c != NULL, 0);
if (!c->active)
res = c->latency.num;
if (c->active || res == (uint32_t)-1) {
res = c->buffer_frames;
if (res == (uint32_t)-1) {
if (c->rt.position)
res = c->rt.position->clock.duration;
else if (c->position)
res = c->position->clock.duration;
}
}
c->buffer_frames = res;
pw_log_debug("buffer_frames: %u", res);
return res;
}
SPA_EXPORT
int jack_engine_takeover_timebase (jack_client_t *client)
{
pw_log_error("%p: deprecated", client);
return 0;
}
SPA_EXPORT
float jack_cpu_load (jack_client_t *client)
{
struct client *c = (struct client *) client;
float res = 0.0f;
return_val_if_fail(c != NULL, 0.0);
if (c->driver_activation)
res = c->driver_activation->cpu_load[0] * 100.0f;
pw_log_trace("%p: cpu load %f", client, res);
return res;
}
#include "statistics.c"
static void *get_buffer_input_float(struct port *p, jack_nframes_t frames);
static void *get_buffer_input_midi(struct port *p, jack_nframes_t frames);
static void *get_buffer_input_empty(struct port *p, jack_nframes_t frames);
static void *get_buffer_output_float(struct port *p, jack_nframes_t frames);
static void *get_buffer_output_midi(struct port *p, jack_nframes_t frames);
static void *get_buffer_output_empty(struct port *p, jack_nframes_t frames);
SPA_EXPORT
jack_port_t * jack_port_register (jack_client_t *client,
const char *port_name,
const char *port_type,
unsigned long flags,
unsigned long buffer_frames)
{
struct client *c = (struct client *) client;
enum spa_direction direction;
struct object *o;
jack_port_type_id_t type_id;
uint8_t buffer[1024];
struct spa_pod_builder b = SPA_POD_BUILDER_INIT(buffer, sizeof(buffer));
struct spa_pod *params[7];
uint32_t n_params = 0;
struct port *p;
int res, len;
char name[REAL_JACK_PORT_NAME_SIZE+1];
return_val_if_fail(c != NULL, NULL);
return_val_if_fail(port_name != NULL && strlen(port_name) != 0, NULL);
return_val_if_fail(port_type != NULL, NULL);
pw_log_info("%p: port register \"%s:%s\" \"%s\" %08lx %ld",
c, c->name, port_name, port_type, flags, buffer_frames);
if (flags & JackPortIsInput)
direction = PW_DIRECTION_INPUT;
else if (flags & JackPortIsOutput)
direction = PW_DIRECTION_OUTPUT;
else {
pw_log_warn("invalid port flags %lu for %s", flags, port_name);
return NULL;
}
if ((type_id = string_to_type(port_type)) == SPA_ID_INVALID) {
pw_log_warn("unknown port type %s", port_type);
return NULL;
}
if (type_id == TYPE_ID_MIDI && (flags & JackPortIsMIDI2))
type_id = TYPE_ID_UMP;
len = snprintf(name, sizeof(name), "%s:%s", c->name, port_name);
if (len < 0 || (size_t)len >= sizeof(name)) {
pw_log_warn("%p: name \"%s:%s\" too long", c,
c->name, port_name);
return NULL;
}
pthread_mutex_lock(&c->context.lock);
o = find_port_by_name(c, name);
pthread_mutex_unlock(&c->context.lock);
if (o != NULL) {
pw_log_warn("%p: name \"%s\" already exists", c, name);
return NULL;
}
if ((p = alloc_port(c, direction)) == NULL) {
pw_log_warn("can't allocate port %s: %m", port_name);
return NULL;
}
o = p->object;
o->port.flags = flags;
strcpy(o->port.name, name);
o->port.type_id = type_id;
init_buffer(p, c->max_frames);
if (direction == SPA_DIRECTION_INPUT) {
switch (type_id) {
case TYPE_ID_AUDIO:
case TYPE_ID_VIDEO:
p->get_buffer = get_buffer_input_float;
break;
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
p->get_buffer = get_buffer_input_midi;
break;
default:
p->get_buffer = get_buffer_input_empty;
break;
}
} else {
switch (type_id) {
case TYPE_ID_AUDIO:
case TYPE_ID_VIDEO:
p->get_buffer = get_buffer_output_float;
break;
case TYPE_ID_MIDI:
case TYPE_ID_OSC:
case TYPE_ID_UMP:
p->get_buffer = get_buffer_output_midi;
break;
default:
p->get_buffer = get_buffer_output_empty;
break;
}
}
pw_log_debug("%p: port %p", c, p);
spa_list_init(&p->mix);
pw_properties_set(p->props, PW_KEY_FORMAT_DSP, type_to_string(type_id));
pw_properties_set(p->props, PW_KEY_PORT_NAME, port_name);
if (flags > 0x1f) {
pw_properties_setf(p->props, PW_KEY_PORT_EXTRA,
"jack:flags:%lu", flags & ~0x1f);
}
if (flags & JackPortIsPhysical)
pw_properties_set(p->props, PW_KEY_PORT_PHYSICAL, "true");
if (flags & JackPortIsTerminal)
pw_properties_set(p->props, PW_KEY_PORT_TERMINAL, "true");
p->info = SPA_PORT_INFO_INIT();
p->info.change_mask |= SPA_PORT_CHANGE_MASK_FLAGS;
p->info.flags = SPA_PORT_FLAG_NO_REF;
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PROPS;
p->info.props = &p->props->dict;
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PARAMS;
p->params[IDX_EnumFormat] = SPA_PARAM_INFO(SPA_PARAM_EnumFormat, SPA_PARAM_INFO_READ);
p->params[IDX_Buffers] = SPA_PARAM_INFO(SPA_PARAM_Buffers, SPA_PARAM_INFO_READ);
p->params[IDX_IO] = SPA_PARAM_INFO(SPA_PARAM_IO, SPA_PARAM_INFO_READ);
p->params[IDX_Format] = SPA_PARAM_INFO(SPA_PARAM_Format, SPA_PARAM_INFO_WRITE);
p->params[IDX_Latency] = SPA_PARAM_INFO(SPA_PARAM_Latency, SPA_PARAM_INFO_READWRITE);
p->info.params = p->params;
p->info.n_params = N_PORT_PARAMS;
param_enum_format(c, p, &params[n_params++], &b);
param_buffers(c, p, &params[n_params++], &b);
param_io(c, p, &params[n_params++], &b);
param_io_async(c, p, &params[n_params++], &b);
param_latency(c, p, &params[n_params++], &b);
param_latency_other(c, p, &params[n_params++], &b);
pw_thread_loop_lock(c->context.loop);
if (create_mix(c, p, SPA_ID_INVALID, SPA_ID_INVALID) == NULL) {
res = -errno;
pw_log_warn("can't create mix for port %s: %m", port_name);
pw_thread_loop_unlock(c->context.loop);
goto error_free;
}
freeze_callbacks(c);
pw_client_node_port_update(c->node,
direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_PARAMS |
PW_CLIENT_NODE_PORT_UPDATE_INFO,
n_params,
(const struct spa_pod **) params,
&p->info);
p->info.change_mask = 0;
res = do_sync(c);
thaw_callbacks(c);
pw_log_debug("%p: port %p done", c, p);
pw_thread_loop_unlock(c->context.loop);
if (res < 0) {
pw_log_warn("can't create port %s: %s", port_name,
spa_strerror(res));
goto error_free;
}
return object_to_port(o);
error_free:
free_port(c, p, true);
return NULL;
}
static int
do_free_port(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct port *p = user_data;
struct client *c = p->client;
free_port(c, p, !c->active);
return 0;
}
static int
do_invalidate_port(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct port *p = user_data;
struct client *c = p->client;
p->valid = false;
pw_loop_invoke(c->context.l, do_free_port, 0, NULL, 0, false, p);
return 0;
}
SPA_EXPORT
int jack_port_unregister (jack_client_t *client, jack_port_t *port)
{
struct client *c = (struct client *) client;
struct object *o = port_to_object(port);
struct port *p;
int res;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(o != NULL, -EINVAL);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
p = o->port.port;
if (o->type != INTERFACE_Port || p == NULL || !p->valid ||
o->client != c) {
pw_log_error("%p: invalid port %p", client, port);
res = -EINVAL;
goto done;
}
pw_data_loop_invoke(c->loop, do_invalidate_port, 1, NULL, 0, false, p);
pw_log_info("%p: port %p unregister \"%s\"", client, port, o->port.name);
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
0, 0, NULL, NULL);
res = do_sync(c);
if (res < 0) {
pw_log_warn("can't unregister port %s: %s", o->port.name,
spa_strerror(res));
}
done:
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return res;
}
static struct buffer *get_mix_buffer(struct client *c, struct mix *mix, jack_nframes_t frames)
{
struct spa_io_buffers *io;
uint32_t cycle = c->rt.position->clock.cycle & 1;
if (mix->peer_port != NULL)
prepare_output(mix->peer_port, frames, cycle);
io = mix->io[cycle];
if (io == NULL ||
io->status != SPA_STATUS_HAVE_DATA ||
io->buffer_id >= mix->n_buffers)
return NULL;
return &mix->buffers[io->buffer_id];
}
static inline void *get_buffer_data(struct buffer *b, jack_nframes_t frames)
{
struct spa_data *d;
uint32_t offset, size;
d = &b->datas[0];
offset = SPA_MIN(d->chunk->offset, d->maxsize);
size = SPA_MIN(d->chunk->size, d->maxsize - offset);
if (size / sizeof(float) < frames)
return NULL;
return SPA_PTROFF(d->data, offset, void);
}
static void *get_buffer_input_float(struct port *p, jack_nframes_t frames)
{
struct mix *mix;
struct buffer *b;
void *ptr = NULL;
float *mix_ptr[MAX_MIX], *np;
uint32_t n_ptr = 0;
bool ptr_aligned = true;
struct client *c = p->client;
spa_list_for_each(mix, &p->mix, port_link) {
if (mix->id == SPA_ID_INVALID)
continue;
pw_log_trace_fp("%p: port %s mix %d.%d get buffer %d",
c, p->object->port.name, p->port_id, mix->id, frames);
if ((b = get_mix_buffer(c, mix, frames)) == NULL)
continue;
if ((np = get_buffer_data(b, frames)) == NULL)
continue;
if (!SPA_IS_ALIGNED(np, 16))
ptr_aligned = false;
mix_ptr[n_ptr++] = np;
if (n_ptr == MAX_MIX)
break;
}
if (n_ptr == 1) {
ptr = mix_ptr[0];
} else if (n_ptr > 1) {
ptr = p->emptyptr;
c->mix_function(ptr, mix_ptr, n_ptr, ptr_aligned, frames);
p->zeroed = false;
}
if (ptr == NULL)
ptr = init_buffer(p, frames);
return ptr;
}
static void *get_buffer_input_midi(struct port *p, jack_nframes_t frames)
{
struct mix *mix;
void *ptr = p->emptyptr;
struct midi_buffer *mb = (struct midi_buffer*)midi_scratch;
struct mix_info *mix_info[MAX_MIX];
uint32_t n_mix_info = 0;
spa_list_for_each(mix, &p->mix, port_link) {
struct spa_data *d;
struct buffer *b;
struct mix_info *mi = &mix->mix_info;
struct spa_pod_sequence seq;
const void *seq_body;
if (mix->id == SPA_ID_INVALID)
continue;
pw_log_trace_fp("%p: port %p mix %d.%d get buffer %d",
p->client, p, p->port_id, mix->id, frames);
if ((b = get_mix_buffer(p->client, mix, frames)) == NULL)
continue;
d = &b->datas[0];
spa_pod_parser_init_from_data(&mi->parser, d->data, d->maxsize,
d->chunk->offset, d->chunk->size);
if (spa_pod_parser_push_sequence_body(&mi->parser,
&mi->frame, &seq, &seq_body) < 0)
continue;
if (spa_pod_parser_get_control_body(&mi->parser,
&mi->control, &mi->control_body) < 0)
continue;
mix_info[n_mix_info++] = mi;
if (n_mix_info == MAX_MIX)
break;
}
midi_init_buffer(mb, MIDI_SCRATCH_FRAMES, frames);
/* first convert to a thread local scratch buffer, then memcpy into
* the per port buffer. This makes it possible to call this function concurrently
* but also have different pointers per port */
convert_to_event(mix_info, n_mix_info, mb, p->client->fix_midi_events, p->object->port.type_id);
memcpy(ptr, mb, sizeof(struct midi_buffer) + (mb->event_count
* sizeof(struct midi_event)));
if (mb->write_pos > 0) {
size_t offs = mb->buffer_size - mb->write_pos;
memcpy(SPA_PTROFF(ptr, offs, void), SPA_PTROFF(mb, offs, void), mb->write_pos);
}
return ptr;
}
static void *get_buffer_output_float(struct port *p, jack_nframes_t frames)
{
void *ptr;
ptr = get_buffer_output(p, frames, sizeof(float), NULL);
if (SPA_UNLIKELY(p->empty_out = (ptr == NULL)))
ptr = p->emptyptr;
return ptr;
}
static void *get_buffer_output_midi(struct port *p, jack_nframes_t frames)
{
p->empty_out = true;
return p->emptyptr;
}
static void *get_buffer_output_empty(struct port *p, jack_nframes_t frames)
{
p->empty_out = true;
return p->emptyptr;
}
static void *get_buffer_input_empty(struct port *p, jack_nframes_t frames)
{
return init_buffer(p, frames);
}
SPA_EXPORT
void * jack_port_get_buffer (jack_port_t *port, jack_nframes_t frames)
{
struct object *o = port_to_object(port);
struct port *p = NULL;
void *ptr = NULL;
struct client *c;
return_val_if_fail(o != NULL, NULL);
c = o->client;
if (o->type != INTERFACE_Port || c == NULL)
goto done;
if (frames > c->max_frames)
goto done;
if ((p = o->port.port) == NULL) {
struct mix *mix;
struct buffer *b;
if ((mix = find_mix_peer(c, o->id)) == NULL)
goto done;
pw_log_trace("peer mix: %p %d", mix, mix->peer_id);
if ((b = get_mix_buffer(c, mix, frames)) == NULL)
goto done;
if (TYPE_ID_IS_EVENT(o->port.type_id)) {
struct mix_info *mix_info[1], mi;
struct spa_data *d;
struct spa_pod_sequence seq;
const void *seq_body;
ptr = midi_scratch;
midi_init_buffer(ptr, MIDI_SCRATCH_FRAMES, frames);
d = &b->datas[0];
spa_pod_parser_init_from_data(&mi.parser, d->data, d->maxsize,
d->chunk->offset, d->chunk->size);
if (spa_pod_parser_push_sequence_body(&mi.parser,
&mi.frame, &seq, &seq_body) < 0)
goto done;
if (spa_pod_parser_get_control_body(&mi.parser,
&mi.control, &mi.control_body) < 0)
goto done;
mix_info[0] = &mi;
convert_to_event(mix_info, 1, ptr, c->fix_midi_events, o->port.type_id);
} else {
ptr = get_buffer_data(b, frames);
}
} else if (p->valid) {
ptr = p->get_buffer(p, frames);
}
done:
pw_log_trace_fp("%p: port:%p buffer:%p frames:%d", c, p, ptr, frames);
return ptr;
}
SPA_EXPORT
jack_uuid_t jack_port_uuid (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, 0);
return jack_port_uuid_generate(o->serial);
}
static const char *port_name(struct object *o)
{
const char *name;
struct client *c = o->client;
if (c == NULL)
return NULL;
if (c->default_as_system && is_port_default(c, o))
name = o->port.system;
else
name = o->port.name;
return name;
}
SPA_EXPORT
const char * jack_port_name (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, NULL);
if (o->type != INTERFACE_Port)
return NULL;
return port_name(o);
}
SPA_EXPORT
const char * jack_port_short_name (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, NULL);
if (o->type != INTERFACE_Port)
return NULL;
return strchr(port_name(o), ':') + 1;
}
SPA_EXPORT
int jack_port_flags (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, 0);
if (o->type != INTERFACE_Port)
return 0;
return o->port.flags;
}
SPA_EXPORT
const char * jack_port_type (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, NULL);
if (o->type != INTERFACE_Port)
return NULL;
return type_to_string(o->port.type_id);
}
SPA_EXPORT
jack_port_type_id_t jack_port_type_id (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, 0);
if (o->type != INTERFACE_Port)
return TYPE_ID_OTHER;
return o->port.type_id;
}
SPA_EXPORT
int jack_port_is_mine (const jack_client_t *client, const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, 0);
return o->type == INTERFACE_Port &&
o->port.port != NULL &&
o->port.port->client == (struct client*)client;
}
SPA_EXPORT
int jack_port_connected (const jack_port_t *port)
{
struct object *o = port_to_object(port);
struct client *c;
struct object *l;
int res = 0;
return_val_if_fail(o != NULL, 0);
if (o->type != INTERFACE_Port || o->client == NULL)
return 0;
c = o->client;
pthread_mutex_lock(&c->context.lock);
spa_list_for_each(l, &c->context.objects, link) {
if (l->type != INTERFACE_Link || l->removed)
continue;
if (l->port_link.src_serial == o->serial ||
l->port_link.dst_serial == o->serial)
res++;
}
pthread_mutex_unlock(&c->context.lock);
pw_log_debug("%p: id:%u/%u res:%d", port, o->id, o->serial, res);
return res;
}
SPA_EXPORT
int jack_port_connected_to (const jack_port_t *port,
const char *port_name)
{
struct object *o = port_to_object(port);
struct client *c;
struct object *p, *l;
int res = 0;
return_val_if_fail(o != NULL, 0);
return_val_if_fail(port_name != NULL, 0);
if (o->type != INTERFACE_Port || o->client == NULL)
return 0;
c = o->client;
pthread_mutex_lock(&c->context.lock);
p = find_port_by_name(c, port_name);
if (p == NULL)
goto exit;
if (GET_DIRECTION(p->port.flags) == GET_DIRECTION(o->port.flags))
goto exit;
if (p->port.flags & JackPortIsOutput) {
l = p;
p = o;
o = l;
}
if ((l = find_link(c, o->id, p->id)) != NULL)
res = 1;
exit:
pthread_mutex_unlock(&c->context.lock);
pw_log_debug("%p: id:%u/%u name:%s res:%d", port, o->id,
o->serial, port_name, res);
return res;
}
SPA_EXPORT
const char ** jack_port_get_connections (const jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, NULL);
if (o->type != INTERFACE_Port || o->client == NULL)
return NULL;
return jack_port_get_all_connections((jack_client_t *)o->client, port);
}
SPA_EXPORT
const char ** jack_port_get_all_connections (const jack_client_t *client,
const jack_port_t *port)
{
struct client *c = (struct client *) client;
struct object *o = port_to_object(port);
struct object *p, *l;
const char **res;
int count = 0;
struct pw_array tmp;
return_val_if_fail(c != NULL, NULL);
return_val_if_fail(o != NULL, NULL);
pw_array_init(&tmp, sizeof(void*) * 32);
pthread_mutex_lock(&c->context.lock);
spa_list_for_each(l, &c->context.objects, link) {
if (l->type != INTERFACE_Link || l->removed)
continue;
if (l->port_link.src_serial == o->serial)
p = find_type(c, l->port_link.dst, INTERFACE_Port, true);
else if (l->port_link.dst_serial == o->serial)
p = find_type(c, l->port_link.src, INTERFACE_Port, true);
else
continue;
if (p == NULL)
continue;
pw_array_add_ptr(&tmp, (void*)port_name(p));
count++;
}
pthread_mutex_unlock(&c->context.lock);
if (count == 0) {
pw_array_clear(&tmp);
res = NULL;
} else {
pw_array_add_ptr(&tmp, NULL);
res = tmp.data;
}
return res;
}
SPA_EXPORT
int jack_port_tie (jack_port_t *src, jack_port_t *dst)
{
struct object *s = port_to_object(src);
struct object *d = port_to_object(dst);
struct port *sp, *dp;
sp = s->port.port;
dp = d->port.port;
if (sp == NULL || !sp->valid ||
dp == NULL || !dp->valid ||
sp->client != dp->client)
return -EINVAL;
dp->tied = sp;
return 0;
}
SPA_EXPORT
int jack_port_untie (jack_port_t *port)
{
struct object *o = port_to_object(port);
struct port *p;
p = o->port.port;
if (p == NULL || !p->valid)
return -EINVAL;
p->tied = NULL;
return 0;
}
SPA_EXPORT
int jack_port_set_name (jack_port_t *port, const char *port_name)
{
pw_log_warn("deprecated");
return 0;
}
SPA_EXPORT
int jack_port_rename (jack_client_t* client, jack_port_t *port, const char *port_name)
{
struct client *c = (struct client *) client;
struct object *o = port_to_object(port);
struct port *p;
int res = 0;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(o != NULL, -EINVAL);
return_val_if_fail(port_name != NULL, -EINVAL);
pw_thread_loop_lock(c->context.loop);
pw_log_info("%p: port rename %p %s -> %s:%s",
client, port, o->port.name, c->name, port_name);
p = o->port.port;
if (p == NULL || !p->valid) {
res = -EINVAL;
goto done;
}
pw_properties_set(p->props, PW_KEY_PORT_NAME, port_name);
snprintf(o->port.name, sizeof(o->port.name), "%s:%s", c->name, port_name);
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PROPS;
p->info.props = &p->props->dict;
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_INFO,
0, NULL,
&p->info);
p->info.change_mask = 0;
done:
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_port_set_alias (jack_port_t *port, const char *alias)
{
struct object *o = port_to_object(port);
struct client *c;
struct port *p;
const char *key;
int res = 0;
return_val_if_fail(o != NULL, -EINVAL);
return_val_if_fail(alias != NULL, -EINVAL);
c = o->client;
if (o->type != INTERFACE_Port || c == NULL)
return -EINVAL;
pw_thread_loop_lock(c->context.loop);
p = o->port.port;
if (p == NULL || !p->valid) {
res = -EINVAL;
goto done;
}
if (o->port.alias1[0] == '\0') {
key = PW_KEY_OBJECT_PATH;
snprintf(o->port.alias1, sizeof(o->port.alias1), "%s", alias);
}
else if (o->port.alias2[0] == '\0') {
key = PW_KEY_PORT_ALIAS;
snprintf(o->port.alias2, sizeof(o->port.alias2), "%s", alias);
}
else {
res = -1;
goto done;
}
pw_properties_set(p->props, key, alias);
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PROPS;
p->info.props = &p->props->dict;
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_INFO,
0, NULL,
&p->info);
p->info.change_mask = 0;
done:
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_port_unset_alias (jack_port_t *port, const char *alias)
{
struct object *o = port_to_object(port);
struct client *c;
struct port *p;
const char *key;
int res = 0;
return_val_if_fail(o != NULL, -EINVAL);
return_val_if_fail(alias != NULL, -EINVAL);
c = o->client;
if (o->type != INTERFACE_Port || c == NULL)
return -EINVAL;
pw_thread_loop_lock(c->context.loop);
p = o->port.port;
if (p == NULL || !p->valid) {
res = -EINVAL;
goto done;
}
if (spa_streq(o->port.alias1, alias))
key = PW_KEY_OBJECT_PATH;
else if (spa_streq(o->port.alias2, alias))
key = PW_KEY_PORT_ALIAS;
else {
res = -1;
goto done;
}
pw_properties_set(p->props, key, NULL);
p->info.change_mask |= SPA_PORT_CHANGE_MASK_PROPS;
p->info.props = &p->props->dict;
pw_client_node_port_update(c->node,
p->direction,
p->port_id,
PW_CLIENT_NODE_PORT_UPDATE_INFO,
0, NULL,
&p->info);
p->info.change_mask = 0;
done:
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_port_get_aliases (const jack_port_t *port, char* const aliases[2])
{
struct object *o = port_to_object(port);
int res = 0;
return_val_if_fail(o != NULL, -EINVAL);
return_val_if_fail(aliases != NULL, -EINVAL);
return_val_if_fail(aliases[0] != NULL, -EINVAL);
return_val_if_fail(aliases[1] != NULL, -EINVAL);
if (o->port.alias1[0] != '\0') {
snprintf(aliases[0], REAL_JACK_PORT_NAME_SIZE+1, "%s", o->port.alias1);
res++;
}
if (o->port.alias2[0] != '\0') {
snprintf(aliases[1], REAL_JACK_PORT_NAME_SIZE+1, "%s", o->port.alias2);
res++;
}
return res;
}
SPA_EXPORT
int jack_port_request_monitor (jack_port_t *port, int onoff)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, -EINVAL);
if (onoff)
o->port.monitor_requests++;
else if (o->port.monitor_requests > 0)
o->port.monitor_requests--;
return 0;
}
SPA_EXPORT
int jack_port_request_monitor_by_name (jack_client_t *client,
const char *port_name, int onoff)
{
struct client *c = (struct client *) client;
struct object *p;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(port_name != NULL, -EINVAL);
pthread_mutex_lock(&c->context.lock);
p = find_port_by_name(c, port_name);
pthread_mutex_unlock(&c->context.lock);
if (p == NULL) {
pw_log_error("%p: jack_port_request_monitor_by_name called"
" with an incorrect port %s", client, port_name);
return -1;
}
return jack_port_request_monitor(object_to_port(p), onoff);
}
SPA_EXPORT
int jack_port_ensure_monitor (jack_port_t *port, int onoff)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, -EINVAL);
if (onoff) {
if (o->port.monitor_requests == 0)
o->port.monitor_requests++;
} else {
if (o->port.monitor_requests > 0)
o->port.monitor_requests = 0;
}
return 0;
}
SPA_EXPORT
int jack_port_monitoring_input (jack_port_t *port)
{
struct object *o = port_to_object(port);
return_val_if_fail(o != NULL, -EINVAL);
return o->port.monitor_requests > 0;
}
static void link_proxy_error(void *data, int seq, int res, const char *message)
{
int *link_res = data;
*link_res = res;
}
static const struct pw_proxy_events link_proxy_events = {
PW_VERSION_PROXY_EVENTS,
.error = link_proxy_error,
};
static int check_connect(struct client *c, struct object *src, struct object *dst)
{
int src_self, dst_self, sum;
src_self = src->port.node_id == c->node_id ? 1 : 0;
dst_self = dst->port.node_id == c->node_id ? 1 : 0;
sum = src_self + dst_self;
pw_log_debug("sum %d %d", sum, c->self_connect_mode);
/* check for other connection first */
if (sum == 0)
return c->other_connect_mode;
if (c->self_connect_mode == SELF_CONNECT_ALLOW)
return 1;
/* internal connection */
if (sum == 2 &&
(c->self_connect_mode == SELF_CONNECT_FAIL_EXT ||
c->self_connect_mode == SELF_CONNECT_IGNORE_EXT))
return 1;
/* failure -> -1 */
if (c->self_connect_mode < 0)
return -1;
/* ignore -> 0 */
return 0;
}
SPA_EXPORT
int jack_connect (jack_client_t *client,
const char *source_port,
const char *destination_port)
{
struct client *c = (struct client *) client;
struct object *src, *dst;
struct spa_dict props;
struct spa_dict_item items[6];
struct pw_proxy *proxy;
struct spa_hook listener;
char val[4][16];
int res, link_res = 0;
return_val_if_fail(c != NULL, EINVAL);
return_val_if_fail(source_port != NULL, EINVAL);
return_val_if_fail(destination_port != NULL, EINVAL);
pw_log_info("%p: connect %s %s", client, source_port, destination_port);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
src = find_port_by_name(c, source_port);
dst = find_port_by_name(c, destination_port);
if (src == NULL || dst == NULL ||
!(src->port.flags & JackPortIsOutput) ||
!(dst->port.flags & JackPortIsInput) ||
!TYPE_ID_IS_COMPATIBLE(src->port.type_id, dst->port.type_id)) {
res = -EINVAL;
goto exit;
}
if ((res = check_connect(c, src, dst)) != 1)
goto exit;
snprintf(val[0], sizeof(val[0]), "%d", src->port.node_id);
snprintf(val[1], sizeof(val[1]), "%d", src->id);
snprintf(val[2], sizeof(val[2]), "%d", dst->port.node_id);
snprintf(val[3], sizeof(val[3]), "%d", dst->id);
props = SPA_DICT_INIT(items, 0);
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_LINK_OUTPUT_NODE, val[0]);
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_LINK_OUTPUT_PORT, val[1]);
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_LINK_INPUT_NODE, val[2]);
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_LINK_INPUT_PORT, val[3]);
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_OBJECT_LINGER, "true");
if (c->passive_links)
items[props.n_items++] = SPA_DICT_ITEM_INIT(PW_KEY_LINK_PASSIVE, "true");
proxy = pw_core_create_object(c->core,
"link-factory",
PW_TYPE_INTERFACE_Link,
PW_VERSION_LINK,
&props,
0);
if (proxy == NULL) {
res = -errno;
goto exit;
}
spa_zero(listener);
pw_proxy_add_listener(proxy, &listener, &link_proxy_events, &link_res);
res = do_sync(c);
spa_hook_remove(&listener);
if (link_res < 0)
res = link_res;
pw_proxy_destroy(proxy);
exit:
pw_log_debug("%p: connect %s %s done %d", client, source_port, destination_port, res);
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return -res;
}
SPA_EXPORT
int jack_disconnect (jack_client_t *client,
const char *source_port,
const char *destination_port)
{
struct client *c = (struct client *) client;
struct object *src, *dst, *l;
int res;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(source_port != NULL, -EINVAL);
return_val_if_fail(destination_port != NULL, -EINVAL);
pw_log_info("%p: disconnect %s %s", client, source_port, destination_port);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
src = find_port_by_name(c, source_port);
dst = find_port_by_name(c, destination_port);
pw_log_debug("%p: %d %d", client, src->id, dst->id);
if (src == NULL || dst == NULL ||
!(src->port.flags & JackPortIsOutput) ||
!(dst->port.flags & JackPortIsInput)) {
res = -EINVAL;
goto exit;
}
if ((res = check_connect(c, src, dst)) != 1)
goto exit;
if ((l = find_link(c, src->id, dst->id)) == NULL) {
res = -ENOENT;
goto exit;
}
pw_registry_destroy(c->registry, l->id);
res = do_sync(c);
exit:
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return -res;
}
SPA_EXPORT
int jack_port_disconnect (jack_client_t *client, jack_port_t *port)
{
struct client *c = (struct client *) client;
struct object *o = port_to_object(port);
struct object *l;
int res;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(o != NULL, -EINVAL);
pw_log_debug("%p: disconnect %p", client, port);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
spa_list_for_each(l, &c->context.objects, link) {
if (l->type != INTERFACE_Link || l->removed)
continue;
if (l->port_link.src_serial == o->serial ||
l->port_link.dst_serial == o->serial) {
pw_registry_destroy(c->registry, l->id);
}
}
res = do_sync(c);
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return -res;
}
SPA_EXPORT
int jack_port_name_size(void)
{
return REAL_JACK_PORT_NAME_SIZE+1;
}
SPA_EXPORT
int jack_port_type_size(void)
{
return JACK_PORT_TYPE_SIZE+1;
}
SPA_EXPORT
size_t jack_port_type_get_buffer_size (jack_client_t *client, const char *port_type)
{
struct client *c = (struct client *) client;
return_val_if_fail(client != NULL, 0);
return_val_if_fail(port_type != NULL, 0);
if (spa_streq(JACK_DEFAULT_AUDIO_TYPE, port_type))
return jack_get_buffer_size(client) * sizeof(float);
else if (spa_streq(JACK_DEFAULT_MIDI_TYPE, port_type))
return c->max_frames * sizeof(float);
else if (spa_streq(JACK_DEFAULT_OSC_TYPE, port_type))
return c->max_frames * sizeof(float);
else if (spa_streq(JACK_DEFAULT_UMP_TYPE, port_type))
return c->max_frames * sizeof(float);
else if (spa_streq(JACK_DEFAULT_VIDEO_TYPE, port_type))
return 320 * 240 * 4 * sizeof(float);
else
return 0;
}
SPA_EXPORT
void jack_port_set_latency (jack_port_t *port, jack_nframes_t frames)
{
struct object *o = port_to_object(port);
struct client *c;
jack_latency_range_t range = { frames, frames };
return_if_fail(o != NULL);
c = o->client;
pw_log_debug("%p: %s set latency %d", c, o->port.name, frames);
if (o->port.flags & JackPortIsOutput) {
jack_port_set_latency_range(port, JackCaptureLatency, &range);
}
if (o->port.flags & JackPortIsInput) {
jack_port_set_latency_range(port, JackPlaybackLatency, &range);
}
}
SPA_EXPORT
void jack_port_get_latency_range (jack_port_t *port, jack_latency_callback_mode_t mode, jack_latency_range_t *range)
{
struct object *o = port_to_object(port);
struct client *c;
jack_nframes_t nframes, rate;
int direction;
struct spa_latency_info *info;
int64_t min, max;
return_if_fail(o != NULL);
c = o->client;
if (o->type != INTERFACE_Port || c == NULL) {
range->min = range->max = 0;
return;
}
if (mode == JackCaptureLatency)
direction = SPA_DIRECTION_OUTPUT;
else
direction = SPA_DIRECTION_INPUT;
nframes = jack_get_buffer_size((jack_client_t*)c);
rate = jack_get_sample_rate((jack_client_t*)c);
info = &o->port.latency[direction];
min = (int64_t)(info->min_quantum * nframes) +
info->min_rate +
(info->min_ns * (int64_t)rate) / (int64_t)SPA_NSEC_PER_SEC;
max = (int64_t)(info->max_quantum * nframes) +
info->max_rate +
(info->max_ns * (int64_t)rate) / (int64_t)SPA_NSEC_PER_SEC;
range->min = SPA_MAX(min, 0);
range->max = SPA_MAX(max, 0);
pw_log_debug("%p: %s get %d latency range %d %d", c, o->port.name,
mode, range->min, range->max);
}
static int
do_port_check_latency(struct spa_loop *loop,
bool async, uint32_t seq, const void *data, size_t size, void *user_data)
{
struct port *p = user_data;
const struct spa_latency_info *latency = data;
port_check_latency(p, latency);
return 0;
}
SPA_EXPORT
void jack_port_set_latency_range (jack_port_t *port, jack_latency_callback_mode_t mode, jack_latency_range_t *range)
{
struct object *o = port_to_object(port);
struct client *c;
enum spa_direction direction;
struct spa_latency_info latency;
jack_nframes_t nframes;
struct port *p;
return_if_fail(o != NULL);
if (o->type != INTERFACE_Port || o->client == NULL)
return;
c = o->client;
if (mode == JackCaptureLatency)
direction = SPA_DIRECTION_OUTPUT;
else
direction = SPA_DIRECTION_INPUT;
pw_log_info("%p: %s set %d latency range %d %d", c, o->port.name, mode, range->min, range->max);
latency = SPA_LATENCY_INFO(direction);
nframes = jack_get_buffer_size((jack_client_t*)c);
if (nframes == 0)
nframes = 1;
latency.min_rate = range->min;
if (latency.min_rate >= (int32_t)nframes) {
latency.min_quantum = latency.min_rate / nframes;
latency.min_rate %= nframes;
}
latency.max_rate = range->max;
if (latency.max_rate >= (int32_t)nframes) {
latency.max_quantum = latency.max_rate / nframes;
latency.max_rate %= nframes;
}
if ((p = o->port.port) == NULL)
return;
pw_loop_invoke(c->context.l, do_port_check_latency, 0,
&latency, sizeof(latency), false, p);
}
SPA_EXPORT
int jack_recompute_total_latencies (jack_client_t *client)
{
struct client *c = (struct client *) client;
return queue_notify(c, NOTIFY_TYPE_TOTAL_LATENCY, NULL, 0, NULL);
}
static jack_nframes_t port_get_latency (jack_port_t *port)
{
struct object *o = port_to_object(port);
jack_latency_range_t range = { 0, 0 };
return_val_if_fail(o != NULL, 0);
if (o->port.flags & JackPortIsOutput) {
jack_port_get_latency_range(port, JackCaptureLatency, &range);
}
if (o->port.flags & JackPortIsInput) {
jack_port_get_latency_range(port, JackPlaybackLatency, &range);
}
return (range.min + range.max) / 2;
}
SPA_EXPORT
jack_nframes_t jack_port_get_latency (jack_port_t *port)
{
return port_get_latency(port);
}
SPA_EXPORT
jack_nframes_t jack_port_get_total_latency (jack_client_t *client,
jack_port_t *port)
{
return port_get_latency(port);
}
SPA_EXPORT
int jack_recompute_total_latency (jack_client_t *client, jack_port_t* port)
{
pw_log_warn("%p: not implemented %p", client, port);
return 0;
}
static int port_compare_func(const void *v1, const void *v2)
{
const struct object *const*o1 = v1, *const*o2 = v2;
struct client *c = (*o1)->client;
int res;
bool is_cap1, is_cap2, is_def1 = false, is_def2 = false;
is_cap1 = ((*o1)->port.flags & JackPortIsOutput) == JackPortIsOutput &&
!(*o1)->port.is_monitor;
is_cap2 = ((*o2)->port.flags & JackPortIsOutput) == JackPortIsOutput &&
!(*o2)->port.is_monitor;
if (c->metadata) {
struct object *ot1, *ot2;
ot1 = (*o1)->port.node;
if (is_cap1)
is_def1 = ot1 != NULL && spa_streq(ot1->node.node_name,
c->metadata->default_audio_source);
else if (!is_cap1)
is_def1 = ot1 != NULL && spa_streq(ot1->node.node_name,
c->metadata->default_audio_sink);
ot2 = (*o2)->port.node;
if (is_cap2)
is_def2 = ot2 != NULL && spa_streq(ot2->node.node_name,
c->metadata->default_audio_source);
else if (!is_cap2)
is_def2 = ot2 != NULL && spa_streq(ot2->node.node_name,
c->metadata->default_audio_sink);
}
if ((*o1)->port.type_id != (*o2)->port.type_id)
res = (*o1)->port.type_id - (*o2)->port.type_id;
else if ((is_cap1 || is_cap2) && is_cap1 != is_cap2)
res = is_cap2 - is_cap1;
else if ((is_def1 || is_def2) && is_def1 != is_def2)
res = is_def2 - is_def1;
else if ((*o1)->port.priority != (*o2)->port.priority)
res = (*o2)->port.priority - (*o1)->port.priority;
else if ((res = (*o1)->port.node_id - (*o2)->port.node_id) == 0) {
if ((*o1)->port.is_monitor != (*o2)->port.is_monitor)
res = (*o1)->port.is_monitor - (*o2)->port.is_monitor;
if (res == 0)
res = (*o1)->port.system_id - (*o2)->port.system_id;
if (res == 0)
res = (*o1)->serial - (*o2)->serial;
}
pw_log_debug("port %s<->%s type:%d<->%d def:%d<->%d prio:%d<->%d id:%d<->%d res:%d",
(*o1)->port.name, (*o2)->port.name,
(*o1)->port.type_id, (*o2)->port.type_id,
is_def1, is_def2,
(*o1)->port.priority, (*o2)->port.priority,
(*o1)->serial, (*o2)->serial, res);
return res;
}
SPA_EXPORT
const char ** jack_get_ports (jack_client_t *client,
const char *port_name_pattern,
const char *type_name_pattern,
unsigned long flags)
{
struct client *c = (struct client *) client;
const char **res;
struct object *o;
struct pw_array tmp;
const char *str;
uint32_t i, count;
int r;
regex_t port_regex, type_regex;
return_val_if_fail(c != NULL, NULL);
str = getenv("PIPEWIRE_NODE");
if (port_name_pattern && port_name_pattern[0]) {
if ((r = regcomp(&port_regex, port_name_pattern, REG_EXTENDED | REG_NOSUB)) != 0) {
pw_log_error("can't compile regex %s: %d", port_name_pattern, r);
return NULL;
}
}
if (type_name_pattern && type_name_pattern[0]) {
if ((r = regcomp(&type_regex, type_name_pattern, REG_EXTENDED | REG_NOSUB)) != 0) {
pw_log_error("can't compile regex %s: %d", type_name_pattern, r);
return NULL;
}
}
pw_log_debug("%p: ports target:%s name:\"%s\" type:\"%s\" flags:%08lx", c, str,
port_name_pattern, type_name_pattern, flags);
pthread_mutex_lock(&c->context.lock);
pw_array_init(&tmp, sizeof(void*) * 32);
count = 0;
spa_list_for_each(o, &c->context.objects, link) {
if (o->type != INTERFACE_Port || o->removed || !o->visible)
continue;
pw_log_debug("%p: check port type:%d flags:%08lx name:\"%s\"", c,
o->port.type_id, o->port.flags, o->port.name);
if (TYPE_ID_IS_HIDDEN(o->port.type_id))
continue;
if (!SPA_FLAG_IS_SET(o->port.flags, flags))
continue;
if (str != NULL && o->port.node != NULL) {
if (!spa_strstartswith(o->port.name, str) &&
o->port.node->serial != atoll(str))
continue;
}
if (port_name_pattern && port_name_pattern[0]) {
bool match;
match = regexec(&port_regex, o->port.name, 0, NULL, 0) == 0;
if (!match && is_port_default(c, o))
match = regexec(&port_regex, o->port.system, 0, NULL, 0) == 0;
if (!match)
continue;
}
if (type_name_pattern && type_name_pattern[0]) {
if (regexec(&type_regex, type_to_string(o->port.type_id),
0, NULL, 0) == REG_NOMATCH)
continue;
}
pw_log_debug("%p: port \"%s\" prio:%d matches (%d)",
c, o->port.name, o->port.priority, count);
pw_array_add_ptr(&tmp, o);
count++;
}
pthread_mutex_unlock(&c->context.lock);
if (count > 0) {
qsort(tmp.data, count, sizeof(struct object *), port_compare_func);
pw_array_add_ptr(&tmp, NULL);
res = tmp.data;
for (i = 0; i < count; i++)
res[i] = port_name((struct object*)res[i]);
} else {
pw_array_clear(&tmp);
res = NULL;
}
if (port_name_pattern && port_name_pattern[0])
regfree(&port_regex);
if (type_name_pattern && type_name_pattern[0])
regfree(&type_regex);
return res;
}
SPA_EXPORT
jack_port_t * jack_port_by_name (jack_client_t *client, const char *port_name)
{
struct client *c = (struct client *) client;
struct object *res;
return_val_if_fail(c != NULL, NULL);
pthread_mutex_lock(&c->context.lock);
res = find_port_by_name(c, port_name);
pthread_mutex_unlock(&c->context.lock);
if (res == NULL)
pw_log_info("%p: port \"%s\" not found", c, port_name);
return object_to_port(res);
}
SPA_EXPORT
jack_port_t * jack_port_by_id (jack_client_t *client,
jack_port_id_t port_id)
{
struct client *c = (struct client *) client;
struct object *res = NULL;
return_val_if_fail(c != NULL, NULL);
pthread_mutex_lock(&c->context.lock);
res = find_by_serial(c, port_id);
if (res && res->type != INTERFACE_Port)
res = NULL;
pw_log_debug("%p: port %d -> %p", c, port_id, res);
pthread_mutex_unlock(&c->context.lock);
if (res == NULL)
pw_log_info("%p: port %d not found", c, port_id);
return object_to_port(res);
}
static inline void get_frame_times(struct client *c, struct frame_times *times)
{
jack_unique_t u1;
uint32_t count = 0;
do {
u1 = c->jack_position.unique_1;
*times = c->jack_times;
if (++count == 10) {
pw_log_warn("could not get snapshot %" PRIu64 " %" PRIu64, u1, c->jack_position.unique_2);
break;
}
} while (u1 != c->jack_position.unique_2);
}
SPA_EXPORT
jack_nframes_t jack_frames_since_cycle_start (const jack_client_t *client)
{
struct client *c = (struct client *) client;
struct frame_times times;
int64_t diff;
return_val_if_fail(c != NULL, 0);
get_frame_times(c, &times);
diff = get_time_ns(c->l->system) - times.nsec;
return (jack_nframes_t) floor(((double)times.sample_rate * diff) / SPA_NSEC_PER_SEC);
}
SPA_EXPORT
jack_nframes_t jack_frame_time (const jack_client_t *client)
{
return jack_time_to_frames(client, jack_get_time());
}
SPA_EXPORT
jack_nframes_t jack_last_frame_time (const jack_client_t *client)
{
struct client *c = (struct client *) client;
struct frame_times times;
return_val_if_fail(c != NULL, 0);
get_frame_times(c, &times);
return times.frames;
}
SPA_EXPORT
int jack_get_cycle_times(const jack_client_t *client,
jack_nframes_t *current_frames,
jack_time_t *current_usecs,
jack_time_t *next_usecs,
float *period_usecs)
{
struct client *c = (struct client *) client;
struct frame_times times;
return_val_if_fail(c != NULL, -EINVAL);
get_frame_times(c, &times);
if (times.sample_rate == 0 || times.rate_diff == 0.0)
return -1;
*current_frames = times.frames;
*next_usecs = times.next_nsec / SPA_NSEC_PER_USEC;
*period_usecs = (float)(times.buffer_frames *
SPA_USEC_PER_SEC / (times.sample_rate * times.rate_diff));
*current_usecs = *next_usecs - (jack_time_t)*period_usecs;
pw_log_trace("%p: %d %"PRIu64" %"PRIu64" %f", c, *current_frames,
*current_usecs, *next_usecs, *period_usecs);
return 0;
}
SPA_EXPORT
jack_time_t jack_frames_to_time(const jack_client_t *client, jack_nframes_t frames)
{
struct client *c = (struct client *) client;
struct frame_times times;
return_val_if_fail(c != NULL, -EINVAL);
get_frame_times(c, &times);
if (times.buffer_frames == 0 || times.sample_rate == 0 || times.rate_diff == 0.0)
return 0;
uint32_t nf = (uint32_t)times.frames;
uint64_t nw = times.next_nsec/SPA_NSEC_PER_USEC;
uint64_t dp = (uint64_t)(times.buffer_frames *
(float)SPA_USEC_PER_SEC / (times.sample_rate * times.rate_diff));
uint64_t w = nw - dp;
int32_t df = frames - nf;
return w + (int64_t)rint((double) df * (double) dp / times.buffer_frames);
}
SPA_EXPORT
jack_nframes_t jack_time_to_frames(const jack_client_t *client, jack_time_t usecs)
{
struct client *c = (struct client *) client;
struct frame_times times;
return_val_if_fail(c != NULL, -EINVAL);
get_frame_times(c, &times);
if (times.sample_rate == 0 || times.rate_diff == 0.0)
return 0;
uint32_t nf = (uint32_t)times.frames;
uint64_t nw = times.next_nsec/SPA_NSEC_PER_USEC;
uint64_t dp = (uint64_t)(times.buffer_frames *
(float)SPA_USEC_PER_SEC / (times.sample_rate * times.rate_diff));
uint64_t w = nw - dp;
int64_t du = usecs - w;
return nf + (int32_t)rint((double)du / (double)dp * times.buffer_frames);
}
SPA_EXPORT
jack_time_t jack_get_time(void)
{
struct timespec ts;
clock_gettime(CLOCK_MONOTONIC, &ts);
return SPA_TIMESPEC_TO_USEC(&ts);
}
SPA_EXPORT
void default_jack_error_callback(const char *desc)
{
pw_log_error("pw jack error: %s",desc);
}
SPA_EXPORT
void silent_jack_error_callback(const char *desc)
{
}
SPA_EXPORT
void (*jack_error_callback)(const char *msg);
SPA_EXPORT
void jack_set_error_function (void (*func)(const char *))
{
jack_error_callback = (func == NULL) ? &default_jack_error_callback : func;
}
SPA_EXPORT
void default_jack_info_callback(const char *desc)
{
pw_log_info("pw jack info: %s", desc);
}
SPA_EXPORT
void silent_jack_info_callback(const char *desc)
{
}
SPA_EXPORT
void (*jack_info_callback)(const char *msg);
SPA_EXPORT
void jack_set_info_function (void (*func)(const char *))
{
jack_info_callback = (func == NULL) ? &default_jack_info_callback : func;
}
SPA_EXPORT
void jack_free(void* ptr)
{
free(ptr);
}
SPA_EXPORT
int jack_release_timebase (jack_client_t *client)
{
struct client *c = (struct client *) client;
struct pw_node_activation *a;
return_val_if_fail(c != NULL, -EINVAL);
if ((a = c->driver_activation) == NULL)
return -EIO;
if (!SPA_ATOMIC_CAS(a->segment_owner[0], c->node_id, 0))
return -EINVAL;
c->timebase_callback = NULL;
c->timebase_arg = NULL;
c->activation->pending_new_pos = false;
return 0;
}
SPA_EXPORT
int jack_set_sync_callback (jack_client_t *client,
JackSyncCallback sync_callback,
void *arg)
{
int res = 0;
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
c->sync_callback = sync_callback;
c->sync_arg = arg;
if ((res = do_activate(c)) < 0)
goto done;
c->activation->pending_sync = true;
done:
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_set_sync_timeout (jack_client_t *client,
jack_time_t timeout)
{
int res = 0;
struct client *c = (struct client *) client;
struct pw_node_activation *a;
return_val_if_fail(c != NULL, -EINVAL);
pw_thread_loop_lock(c->context.loop);
if ((a = c->activation) == NULL)
res = -EIO;
else
a->sync_timeout = timeout;
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_set_timebase_callback (jack_client_t *client,
int conditional,
JackTimebaseCallback timebase_callback,
void *arg)
{
int res = 0;
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
return_val_if_fail(timebase_callback != NULL, -EINVAL);
pw_thread_loop_lock(c->context.loop);
freeze_callbacks(c);
c->timebase_callback = timebase_callback;
c->timebase_arg = arg;
c->timeowner_conditional = conditional;
install_timeowner(c);
pw_log_debug("%p: timebase set id:%u", c, c->node_id);
if ((res = do_activate(c)) < 0)
goto done;
c->activation->pending_new_pos = true;
done:
thaw_callbacks(c);
pw_thread_loop_unlock(c->context.loop);
return res;
}
SPA_EXPORT
int jack_transport_locate (jack_client_t *client,
jack_nframes_t frame)
{
jack_position_t pos;
pos.frame = frame;
pos.valid = (jack_position_bits_t)0;
return jack_transport_reposition(client, &pos);
}
SPA_EXPORT
jack_transport_state_t jack_transport_query (const jack_client_t *client,
jack_position_t *pos)
{
struct client *c = (struct client *) client;
jack_transport_state_t state;
jack_unique_t u1;
uint32_t count = 0;
return_val_if_fail(c != NULL, JackTransportStopped);
do {
u1 = c->jack_position.unique_1;
state = c->jack_state;
if (pos != NULL)
*pos = c->jack_position;
if (++count == 10) {
pw_log_warn("could not get snapshot %" PRIu64 " %" PRIu64, u1, c->jack_position.unique_2);
break;
}
} while (u1 != c->jack_position.unique_2);
return state;
}
SPA_EXPORT
jack_nframes_t jack_get_current_transport_frame (const jack_client_t *client)
{
struct client *c = (struct client *) client;
jack_transport_state_t state;
jack_nframes_t res;
jack_position_t pos;
return_val_if_fail(c != NULL, -EINVAL);
state = jack_transport_query(client, &pos);
res = pos.frame;
if (state == JackTransportRolling) {
float usecs = get_time_ns(c->l->system)/1000 - pos.usecs;
res += (jack_nframes_t)floor((((float) pos.frame_rate) / 1000000.0f) * usecs);
}
return res;
}
SPA_EXPORT
int jack_transport_reposition (jack_client_t *client,
const jack_position_t *pos)
{
struct client *c = (struct client *) client;
struct pw_node_activation *a, *na;
return_val_if_fail(c != NULL, -EINVAL);
a = c->rt.driver_activation;
na = c->activation;
if (!a || !na)
return -EIO;
if (pos->valid & ~(JackPositionBBT|JackPositionTimecode))
return -EINVAL;
pw_log_debug("frame:%u", pos->frame);
spa_zero(na->reposition);
na->reposition.flags = 0;
na->reposition.start = 0;
na->reposition.duration = 0;
na->reposition.position = pos->frame;
na->reposition.rate = 1.0;
SPA_ATOMIC_STORE(a->reposition_owner, c->node_id);
return 0;
}
static void update_command(struct client *c, uint32_t command)
{
struct pw_node_activation *a = c->rt.driver_activation;
if (!a)
return;
SPA_ATOMIC_STORE(a->command, command);
}
static int transport_update(struct client* c, int active)
{
pw_log_info("%p: transport %d", c, active);
pw_thread_loop_lock(c->context.loop);
pw_properties_set(c->props, PW_KEY_NODE_SYNC, "true");
pw_properties_set(c->props, PW_KEY_NODE_TRANSPORT,
active ? "true" : "false");
c->info.change_mask |= SPA_NODE_CHANGE_MASK_PROPS;
c->info.props = &c->props->dict;
pw_client_node_update(c->node,
PW_CLIENT_NODE_UPDATE_INFO,
0, NULL, &c->info);
c->info.change_mask = 0;
pw_properties_set(c->props, PW_KEY_NODE_TRANSPORT, NULL);
pw_thread_loop_unlock(c->context.loop);
return 0;
}
SPA_EXPORT
void jack_transport_start (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_if_fail(c != NULL);
if (c->activation->server_version < 1)
update_command(c, PW_NODE_ACTIVATION_COMMAND_START);
else
transport_update(c, true);
}
SPA_EXPORT
void jack_transport_stop (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_if_fail(c != NULL);
if (c->activation->server_version < 1)
update_command(c, PW_NODE_ACTIVATION_COMMAND_STOP);
else
transport_update(c, false);
}
SPA_EXPORT
void jack_get_transport_info (jack_client_t *client,
jack_transport_info_t *tinfo)
{
pw_log_error("%p: deprecated", client);
if (tinfo)
memset(tinfo, 0, sizeof(jack_transport_info_t));
}
SPA_EXPORT
void jack_set_transport_info (jack_client_t *client,
jack_transport_info_t *tinfo)
{
pw_log_error("%p: deprecated", client);
if (tinfo)
memset(tinfo, 0, sizeof(jack_transport_info_t));
}
SPA_EXPORT
int jack_set_session_callback (jack_client_t *client,
JackSessionCallback session_callback,
void *arg)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -EINVAL);
if (c->active) {
pw_log_error("%p: can't set callback on active client", c);
return -EIO;
}
pw_log_warn("%p: not implemented", client);
return -ENOTSUP;
}
SPA_EXPORT
int jack_session_reply (jack_client_t *client,
jack_session_event_t *event)
{
pw_log_warn("%p: not implemented", client);
return -ENOTSUP;
}
SPA_EXPORT
void jack_session_event_free (jack_session_event_t *event)
{
if (event) {
free((void *)event->session_dir);
free((void *)event->client_uuid);
free(event->command_line);
free(event);
}
}
SPA_EXPORT
char *jack_client_get_uuid (jack_client_t *client)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, NULL);
return spa_aprintf("%"PRIu64, client_make_uuid(c->serial, false));
}
SPA_EXPORT
jack_session_command_t *jack_session_notify (
jack_client_t* client,
const char *target,
jack_session_event_type_t type,
const char *path)
{
struct client *c = (struct client *) client;
jack_session_command_t *cmds;
return_val_if_fail(c != NULL, NULL);
pw_log_warn("not implemented");
cmds = calloc(1, sizeof(jack_session_command_t));
return cmds;
}
SPA_EXPORT
void jack_session_commands_free (jack_session_command_t *cmds)
{
int i;
if (cmds == NULL)
return;
for (i = 0; cmds[i].uuid != NULL; i++) {
free((char*)cmds[i].client_name);
free((char*)cmds[i].command);
free((char*)cmds[i].uuid);
}
free(cmds);
}
SPA_EXPORT
int jack_reserve_client_name (jack_client_t *client,
const char *name,
const char *uuid)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -1);
pw_log_warn("not implemented");
return 0;
}
SPA_EXPORT
int jack_client_has_session_callback (jack_client_t *client, const char *client_name)
{
struct client *c = (struct client *) client;
return_val_if_fail(c != NULL, -1);
return 0;
}
SPA_EXPORT
int jack_client_real_time_priority (jack_client_t * client)
{
return jack_client_max_real_time_priority(client) - 5;
}
SPA_EXPORT
int jack_client_max_real_time_priority (jack_client_t *client)
{
struct client *c = (struct client *) client;
int min, max;
return_val_if_fail(c != NULL, -1);
spa_thread_utils_get_rt_range(&c->context.thread_utils, NULL, &min, &max);
return SPA_MIN(max, c->rt_max) - 1;
}
SPA_EXPORT
int jack_acquire_real_time_scheduling (jack_native_thread_t thread, int priority)
{
struct spa_thread *t = (struct spa_thread*)thread;
pw_log_info("acquire %p", t);
return_val_if_fail(globals.thread_utils != NULL, -1);
return_val_if_fail(t != NULL, -1);
return spa_thread_utils_acquire_rt(globals.thread_utils, t, priority);
}
SPA_EXPORT
int jack_drop_real_time_scheduling (jack_native_thread_t thread)
{
struct spa_thread *t = (struct spa_thread*)thread;
pw_log_info("drop %p", t);
return_val_if_fail(globals.thread_utils != NULL, -1);
return_val_if_fail(t != NULL, -1);
return spa_thread_utils_drop_rt(globals.thread_utils, t);
}
/**
* Create a thread for JACK or one of its clients. The thread is
* created executing @a start_routine with @a arg as its sole
* argument.
*
* @param client the JACK client for whom the thread is being created. May be
* NULL if the client is being created within the JACK server.
* @param thread place to return POSIX thread ID.
* @param priority thread priority, if realtime.
* @param realtime true for the thread to use realtime scheduling. On
* some systems that may require special privileges.
* @param start_routine function the thread calls when it starts.
* @param arg parameter passed to the @a start_routine.
*
* @returns 0, if successful; otherwise some error number.
*/
SPA_EXPORT
int jack_client_create_thread (jack_client_t* client,
jack_native_thread_t *thread,
int priority,
int realtime, /* boolean */
void *(*start_routine)(void*),
void *arg)
{
struct client *c = (struct client *) client;
int res = 0;
struct spa_thread *thr;
return_val_if_fail(client != NULL, -EINVAL);
return_val_if_fail(thread != NULL, -EINVAL);
return_val_if_fail(start_routine != NULL, -EINVAL);
pw_log_info("client %p: create thread rt:%d prio:%d", client, realtime, priority);
thr = spa_thread_utils_create(&c->context.thread_utils, NULL, start_routine, arg);
if (thr == NULL)
res = -errno;
*thread = (pthread_t)thr;
if (res != 0) {
pw_log_warn("client %p: create RT thread failed: %s",
client, strerror(res));
} else if (realtime) {
/* Try to acquire RT scheduling, we don't fail here but the
* function will emit a warning. Real JACK fails here. */
jack_acquire_real_time_scheduling(*thread, priority);
}
return res;
}
SPA_EXPORT
int jack_client_stop_thread(jack_client_t* client, jack_native_thread_t thread)
{
struct client *c = (struct client *) client;
void* status;
if (thread == (jack_native_thread_t)NULL)
return -EINVAL;
return_val_if_fail(client != NULL, -EINVAL);
pw_log_debug("join thread %p", (void *) thread);
spa_thread_utils_join(&c->context.thread_utils, (struct spa_thread*)thread, &status);
pw_log_debug("stopped thread %p", (void *) thread);
return 0;
}
SPA_EXPORT
int jack_client_kill_thread(jack_client_t* client, jack_native_thread_t thread)
{
struct client *c = (struct client *) client;
void* status;
if (thread == (jack_native_thread_t)NULL)
return -EINVAL;
return_val_if_fail(client != NULL, -EINVAL);
pw_log_debug("cancel thread %p", (void *) thread);
pthread_cancel(thread);
pw_log_debug("join thread %p", (void *) thread);
spa_thread_utils_join(&c->context.thread_utils, (struct spa_thread*)thread, &status);
pw_log_debug("stopped thread %p", (void *) thread);
return 0;
}
SPA_EXPORT
void jack_set_thread_creator (jack_thread_creator_t creator)
{
globals.creator = creator;
}
static inline uint8_t * midi_event_data (void* port_buffer,
const struct midi_event* event)
{
if (SPA_LIKELY(event->size <= MIDI_INLINE_MAX))
return (uint8_t *)event->inline_data;
else
return SPA_PTROFF(port_buffer, event->byte_offset, uint8_t);
}
SPA_EXPORT
uint32_t jack_midi_get_event_count(void* port_buffer)
{
struct midi_buffer *mb = port_buffer;
if (mb == NULL || mb->magic != MIDI_BUFFER_MAGIC)
return 0;
return mb->event_count;
}
SPA_EXPORT
int jack_midi_event_get(jack_midi_event_t *event,
void *port_buffer,
uint32_t event_index)
{
struct midi_buffer *mb = port_buffer;
struct midi_event *ev = SPA_PTROFF(mb, sizeof(*mb), struct midi_event);
if (mb == NULL || mb->magic != MIDI_BUFFER_MAGIC)
return -EINVAL;
if (event_index >= mb->event_count)
return -ENOBUFS;
ev += event_index;
event->time = ev->time;
event->size = ev->size;
event->buffer = midi_event_data (port_buffer, ev);
return 0;
}
SPA_EXPORT
void jack_midi_clear_buffer(void *port_buffer)
{
struct midi_buffer *mb = port_buffer;
if (mb == NULL || mb->magic != MIDI_BUFFER_MAGIC)
return;
mb->event_count = 0;
mb->write_pos = 0;
mb->lost_events = 0;
}
SPA_EXPORT
void jack_midi_reset_buffer(void *port_buffer)
{
midi_init_buffer(port_buffer, globals.max_frames, globals.max_frames);
}
SPA_EXPORT
size_t jack_midi_max_event_size(void* port_buffer)
{
struct midi_buffer *mb = port_buffer;
size_t buffer_size;
if (mb == NULL || mb->magic != MIDI_BUFFER_MAGIC)
return 0;
buffer_size = mb->buffer_size;
/* (event_count + 1) below accounts for jack_midi_port_internal_event_t
* which would be needed to store the next event */
size_t used_size = sizeof(struct midi_buffer)
+ mb->write_pos
+ ((mb->event_count + 1)
* sizeof(struct midi_event));
if (SPA_UNLIKELY(used_size > buffer_size)) {
return 0;
} else if (SPA_LIKELY((buffer_size - used_size) < MIDI_INLINE_MAX)) {
return MIDI_INLINE_MAX;
} else {
return buffer_size - used_size;
}
}
static inline int midi_buffer_check(void *port_buffer, jack_nframes_t time)
{
struct midi_buffer *mb = port_buffer;
struct midi_event *events;
if (SPA_UNLIKELY(mb == NULL)) {
pw_log_warn("port buffer is NULL");
return -EINVAL;
}
if (SPA_UNLIKELY(mb->magic != MIDI_BUFFER_MAGIC)) {
pw_log_warn("port buffer is invalid");
return -EINVAL;
}
if (SPA_UNLIKELY(time >= mb->nframes)) {
pw_log_warn("midi %p: time:%d frames:%d", port_buffer, time, mb->nframes);
return -EINVAL;
}
events = SPA_PTROFF(mb, sizeof(*mb), struct midi_event);
if (SPA_UNLIKELY(mb->event_count > 0 && time < events[mb->event_count - 1].time)) {
pw_log_warn("midi %p: time:%d ev:%d", port_buffer, time, mb->event_count);
return -EINVAL;
}
return 0;
}
SPA_EXPORT
jack_midi_data_t* jack_midi_event_reserve(void *port_buffer,
jack_nframes_t time,
size_t data_size)
{
struct midi_buffer *mb = port_buffer;
jack_midi_data_t *res;
if (midi_buffer_check(port_buffer, time) < 0)
goto failed;
res = midi_event_reserve(port_buffer, time, data_size);
if (res != NULL)
return res;
failed:
mb->lost_events++;
return NULL;
}
SPA_EXPORT
int jack_midi_event_write(void *port_buffer,
jack_nframes_t time,
const jack_midi_data_t *data,
size_t data_size)
{
jack_midi_data_t *ptr;
int res;
if ((res = midi_buffer_check(port_buffer, time)) < 0)
return res;
if ((ptr = midi_event_reserve(port_buffer, time, data_size)) == NULL)
return -ENOBUFS;
memcpy (ptr, data, data_size);
return 0;
}
SPA_EXPORT
uint32_t jack_midi_get_lost_event_count(void *port_buffer)
{
struct midi_buffer *mb = port_buffer;
if (mb == NULL || mb->magic != MIDI_BUFFER_MAGIC)
return 0;
return mb->lost_events;
}
/** extensions */
SPA_EXPORT
int jack_get_video_image_size(jack_client_t *client, jack_image_size_t *size)
{
struct client *c = (struct client *) client;
struct pw_node_activation *a;
return_val_if_fail(c != NULL, 0);
a = c->rt.driver_activation;
if (SPA_UNLIKELY(a == NULL))
a = c->activation;
if (SPA_UNLIKELY(a == NULL))
return -EIO;
if (SPA_UNLIKELY(!(a->position.video.flags & SPA_IO_VIDEO_SIZE_VALID)))
return -EIO;
size->width = a->position.video.size.width;
size->height = a->position.video.size.height;
size->stride = a->position.video.stride;
size->flags = 0;
return size->stride * size->height;
}
static void reg(void) __attribute__ ((constructor));
static void reg(void)
{
pw_init(NULL, NULL);
PW_LOG_TOPIC_INIT(jack_log_topic);
pthread_mutex_init(&globals.lock, NULL);
pw_array_init(&globals.descriptions, 16);
spa_list_init(&globals.free_objects);
}
static void unreg(void) __attribute__ ((destructor));
static void unreg(void)
{
struct object *o, *to;
pthread_mutex_lock(&globals.lock);
spa_list_for_each_safe(o, to, &globals.free_objects, link) {
if (!o->to_free)
spa_list_remove(&o->link);
}
spa_list_consume(o, &globals.free_objects, link) {
spa_list_remove(&o->link);
free(o);
}
pthread_mutex_unlock(&globals.lock);
pw_deinit();
}
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