/* -*- mode: c; c-file-style: "bsd"; -*- */ /* Copyright (C) 2001-2003 Paul Davis This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. $Id$ */ #include #include #include #include #include #include #ifdef HAVE_STDINT_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include JACK_TIME_GLOBAL_DECL; /* One instance per process. */ #include "local.h" #include #include #ifdef JACK_USE_MACH_THREADS #include #endif #ifdef WITH_TIMESTAMPS #include #endif /* WITH_TIMESTAMPS */ char *jack_server_dir = DEFAULT_TMP_DIR; void jack_set_server_dir (const char *path) { jack_error ("jack_set_server_dir() is deprecated.\n" "Please contact the program's author"); jack_server_dir = strdup (path); } static pthread_mutex_t client_lock; static pthread_cond_t client_ready; void *jack_zero_filled_buffer = NULL; #define EVENT_POLL_INDEX 0 #define WAIT_POLL_INDEX 1 #define event_fd pollfd[EVENT_POLL_INDEX].fd #define graph_wait_fd pollfd[WAIT_POLL_INDEX].fd typedef struct { int status; struct _jack_client *client; const char *client_name; } client_info; void jack_error (const char *fmt, ...) { va_list ap; char buffer[300]; va_start (ap, fmt); vsnprintf (buffer, sizeof(buffer), fmt, ap); jack_error_callback (buffer); va_end (ap); } void default_jack_error_callback (const char *desc) { fprintf(stderr, "%s\n", desc); } void silent_jack_error_callback (const char *desc) { } void (*jack_error_callback)(const char *desc) = &default_jack_error_callback; static int oop_client_deliver_request (void *ptr, jack_request_t *req) { int wok, rok; jack_client_t *client = (jack_client_t*) ptr; wok = (write (client->request_fd, req, sizeof (*req)) == sizeof (*req)); rok = (read (client->request_fd, req, sizeof (*req)) == sizeof (*req)); if (wok && rok) { /* everything OK? */ return req->status; } req->status = -1; /* request failed */ /* check for server shutdown */ if (client->engine->engine_ok == 0) return req->status; /* otherwise report errors */ if (!wok) jack_error ("cannot send request type %d to server", req->type); if (!rok) jack_error ("cannot read result for request type %d from" " server (%s)", req->type, strerror (errno)); return req->status; } int jack_client_deliver_request (const jack_client_t *client, jack_request_t *req) { /* indirect through the function pointer that was set either by jack_client_new() (external) or handle_new_client() in the server. */ return client->control->deliver_request (client->control->deliver_arg, req); } jack_client_t * jack_client_alloc () { jack_client_t *client; client = (jack_client_t *) malloc (sizeof (jack_client_t)); client->pollfd = (struct pollfd *) malloc (sizeof (struct pollfd) * 2); client->pollmax = 2; client->request_fd = -1; client->event_fd = -1; client->upstream_is_jackd = 0; client->graph_wait_fd = -1; client->graph_next_fd = -1; client->ports = NULL; client->engine = NULL; client->control = NULL; client->thread_ok = FALSE; #if JACK_USE_MACH_THREADS client->rt_thread_ok = FALSE; #endif client->first_active = TRUE; client->on_shutdown = NULL; client->n_port_types = 0; client->port_segment = NULL; return client; } /* * Build the jack_client_t structure for an internal client. */ jack_client_t * jack_client_alloc_internal (jack_client_control_t *cc, jack_engine_t* engine) { jack_client_t* client; client = jack_client_alloc (); client->control = cc; client->engine = engine->control; client->n_port_types = client->engine->n_port_types; client->port_segment = &engine->port_segment[0]; return client; } static void jack_client_free (jack_client_t *client) { if (client->pollfd) { free (client->pollfd); } free (client); } void jack_client_invalidate_port_buffers (jack_client_t *client) { JSList *node; jack_port_t *port; /* This releases all local memory owned by input ports and sets the buffer pointer to NULL. This will cause jack_port_get_buffer() to reallocate space for the buffer on the next call (if there is one). */ for (node = client->ports; node; node = jack_slist_next (node)) { port = (jack_port_t *) node->data; if (port->shared->flags & JackPortIsInput) { if (port->mix_buffer) { jack_pool_release (port->mix_buffer); port->mix_buffer = NULL; } } } } int jack_client_handle_port_connection (jack_client_t *client, jack_event_t *event) { jack_port_t *control_port; jack_port_t *other; JSList *node; switch (event->type) { case PortConnected: other = jack_port_new (client, event->y.other_id, client->engine); control_port = jack_port_by_id (client, event->x.self_id); pthread_mutex_lock (&control_port->connection_lock); control_port->connections = jack_slist_prepend (control_port->connections, (void*)other); pthread_mutex_unlock (&control_port->connection_lock); break; case PortDisconnected: control_port = jack_port_by_id (client, event->x.self_id); pthread_mutex_lock (&control_port->connection_lock); for (node = control_port->connections; node; node = jack_slist_next (node)) { other = (jack_port_t *) node->data; if (other->shared->id == event->y.other_id) { control_port->connections = jack_slist_remove_link (control_port->connections, node); jack_slist_free_1 (node); free (other); break; } } pthread_mutex_unlock (&control_port->connection_lock); break; default: /* impossible */ break; } return 0; } static int jack_handle_reorder (jack_client_t *client, jack_event_t *event) { char path[PATH_MAX+1]; if (client->graph_wait_fd >= 0) { DEBUG ("closing graph_wait_fd==%d", client->graph_wait_fd); close (client->graph_wait_fd); client->graph_wait_fd = -1; } if (client->graph_next_fd >= 0) { DEBUG ("closing graph_next_fd==%d", client->graph_next_fd); close (client->graph_next_fd); client->graph_next_fd = -1; } sprintf (path, "%s-%" PRIu32, client->fifo_prefix, event->x.n); if ((client->graph_wait_fd = open (path, O_RDONLY|O_NONBLOCK)) < 0) { jack_error ("cannot open specified fifo [%s] for reading (%s)", path, strerror (errno)); return -1; } DEBUG ("opened new graph_wait_fd %d (%s)", client->graph_wait_fd, path); sprintf (path, "%s-%" PRIu32, client->fifo_prefix, event->x.n+1); if ((client->graph_next_fd = open (path, O_WRONLY|O_NONBLOCK)) < 0) { jack_error ("cannot open specified fifo [%s] for writing (%s)", path, strerror (errno)); return -1; } client->upstream_is_jackd = event->y.n; client->pollmax = 2; DEBUG ("opened new graph_next_fd %d (%s) (upstream is jackd? %d)", client->graph_next_fd, path, client->upstream_is_jackd); /* If the client registered its own callback for graph order events, execute it now. */ if (client->control->graph_order) { client->control->graph_order (client->control->graph_order_arg); } return 0; } static int server_connect (const char *server_name) { int fd; struct sockaddr_un addr; int which = 0; if ((fd = socket (AF_UNIX, SOCK_STREAM, 0)) < 0) { jack_error ("cannot create client socket (%s)", strerror (errno)); return -1; } //JOQ: use server_name as part of socket path addr.sun_family = AF_UNIX; snprintf (addr.sun_path, sizeof (addr.sun_path) - 1, "%s/jack_%d_%d", jack_server_dir, getuid (), which); if (connect (fd, (struct sockaddr *) &addr, sizeof (addr)) < 0) { close (fd); return -1; } return fd; } static int server_event_connect (jack_client_t *client) { int fd; struct sockaddr_un addr; jack_client_connect_ack_request_t req; jack_client_connect_ack_result_t res; if ((fd = socket (AF_UNIX, SOCK_STREAM, 0)) < 0) { jack_error ("cannot create client event socket (%s)", strerror (errno)); return -1; } addr.sun_family = AF_UNIX; snprintf (addr.sun_path, sizeof (addr.sun_path) - 1, "%s/jack_%d_ack_0", jack_server_dir, getuid () ); if (connect (fd, (struct sockaddr *) &addr, sizeof (addr)) < 0) { jack_error ("cannot connect to jack server for events", strerror (errno)); close (fd); return -1; } req.client_id = client->control->id; if (write (fd, &req, sizeof (req)) != sizeof (req)) { jack_error ("cannot write event connect request to server (%s)", strerror (errno)); close (fd); return -1; } if (read (fd, &res, sizeof (res)) != sizeof (res)) { jack_error ("cannot read event connect result from server (%s)", strerror (errno)); close (fd); return -1; } if (res.status != 0) { jack_error ("cannot connect to server for event stream (%s)", strerror (errno)); close (fd); return -1; } return fd; } /* Exec the JACK server in this process. Does not return. */ static void _start_server (const char *server_command) { FILE* fp = 0; char filename[255]; char arguments[255]; char buffer[255]; char* command = 0; size_t pos = 0; size_t result = 0; char** argv = 0; int i = 0; int good = 0; int ret; //JOQ: // if (start_command) { // parse user-supplied command // } else { snprintf(filename, 255, "%s/.jackdrc", getenv("HOME")); fp = fopen(filename, "r"); if (!fp) { fp = fopen("/etc/jackd.conf", "r"); } if (fp) { arguments[0] = '\0'; ret = fscanf(fp, "%s", buffer); while(ret != 0 && ret != EOF) { strcat(arguments, buffer); strcat(arguments, " "); ret = fscanf(fp, "%s", buffer); } if (strlen(arguments) > 0) { good = 1; } } if (!good) { #if defined(USE_CAPABILITIES) command = JACK_LOCATION "/jackstart"; strncpy(arguments, JACK_LOCATION "/jackstart -T -R -d " JACK_DEFAULT_DRIVER " -p 512", 255); #else /* !USE_CAPABILITIES */ command = JACK_LOCATION "/jackd"; strncpy(arguments, JACK_LOCATION "/jackd -T -d " JACK_DEFAULT_DRIVER, 255); #endif /* USE_CAPABILITIES */ } else { result = strcspn(arguments, " "); command = (char *) malloc(result+1); strncpy(command, arguments, result); command[result] = '\0'; } argv = (char **) malloc (255); while(1) { /* insert -T into arguments */ if (i == 1) { argv[i] = (char*)malloc(3); strncpy(argv[i], "-T", 2); argv[i][2] = '\0'; ++i; } result = strcspn(arguments+pos, " "); if (result == 0) { break; } argv[i] = (char*)malloc(result+1); strncpy(argv[i], arguments+pos, result); argv[i][result] = '\0'; pos += result+1; ++i; } argv[i] = 0; execv (command, argv); /* If execv() succeeds, it does not return. There's no point * in calling jack_error() here in the child process. */ perror ("exec of JACK server failed"); } int start_server (jack_options_t options, const char *server_command) { if ((options & JackNoStartServer) || (getenv("JACK_NO_START_SERVER") != NULL)) { return 1; } /* The double fork() forces the server to become a child of * init, which will always clean up zombie process state on * termination. This even works in strange corner cases where * the server terminates but this client does not. * * Since fork() is usually implemented using copy-on-write * virtual memory tricks, the overhead of the second fork() is * probably relatively small. */ switch (fork()) { case 0: /* child process */ switch (fork()) { case 0: /* grandchild process */ _start_server(server_command); _exit (99); /* exec failed */ case -1: _exit (98); default: _exit (0); } case -1: /* fork() error */ return 1; /* failed to start server */ } /* only the original parent process goes here */ return 0; /* (probably) successful */ } static int jack_request_client (ClientType type, const char* client_name, const char* so_name, const char* so_data, jack_client_connect_result_t *res, int *req_fd, jack_options_t options, jack_status_t *status, const char *server_name, const char *server_command) { jack_client_connect_request_t req; *req_fd = -1; memset (&req, 0, sizeof (req)); req.options = options; if (strlen (client_name) >= sizeof (req.name)) { jack_error ("\"%s\" is too long to be used as a JACK client" " name.\n" "Please use %lu characters or less.", client_name, sizeof (req.name)); return -1; } if (strlen (so_name) > sizeof (req.object_path) - 1) { jack_error ("\"%s\" is too long to be used as a JACK shared" " object name.\n" "Please use %lu characters or less.", so_name, sizeof (req.object_path) - 1); return -1; } if (strlen (so_data) > sizeof (req.object_data) - 1) { jack_error ("\"%s\" is too long to be used as a JACK shared" " object data string.\n" "Please use %lu characters or less.", so_data, sizeof (req.object_data) - 1); return -1; } if ((*req_fd = server_connect (server_name)) < 0) { int trys; if (start_server(options, server_command)) { goto fail; } trys = 5; do { sleep(1); if (--trys < 0) { goto fail; } } while ((*req_fd = server_connect (server_name)) < 0); *status |= JackServerStarted; } req.load = TRUE; req.type = type; snprintf (req.name, sizeof (req.name), "%s", client_name); snprintf (req.object_path, sizeof (req.object_path), "%s", so_name); snprintf (req.object_data, sizeof (req.object_data), "%s", so_data); if (write (*req_fd, &req, sizeof (req)) != sizeof (req)) { jack_error ("cannot send request to jack server (%s)", strerror (errno)); goto fail; } if (read (*req_fd, res, sizeof (*res)) != sizeof (*res)) { if (errno == 0) { /* server shut the socket */ jack_error ("could not attach as client " "(duplicate client name?)"); goto fail; } if (errno == ECONNRESET) { jack_error ("could not attach as jack client (server has exited)"); goto fail; } jack_error ("cannot read regsponse from jack server (%s)", strerror (errno)); goto fail; } *status |= res->open_status; /* return server status bits */ //JOQ: fixme overloading confusion if (res->status) { jack_error ("could not attach as client " "(duplicate client name?)"); goto fail; } if (res->protocol_v != jack_protocol_version){ jack_error ("application linked against incompatible libjack" " version."); goto fail; } switch (type) { case ClientDriver: case ClientInternal: close (*req_fd); *req_fd = -1; break; default: break; } return 0; fail: if (*req_fd >= 0) { close (*req_fd); *req_fd = -1; } return -1; } int jack_attach_port_segment (jack_client_t *client, jack_port_type_id_t ptid) { /* Lookup, attach and register the port/buffer segments in use * right now. */ if (client->control->type != ClientExternal) { jack_error("Only external clients need attach port segments"); abort(); } /* make sure we have space to store the port segment information. */ if (ptid >= client->n_port_types) { client->port_segment = (jack_shm_info_t*) realloc (client->port_segment, sizeof (jack_shm_info_t) * (ptid+1)); memset (&client->port_segment[client->n_port_types], 0, sizeof (jack_shm_info_t) * (ptid - client->n_port_types)); client->n_port_types = ptid + 1; } else { /* release any previous segment */ #if JACK_USE_MACH_THREADS /* Stephane Letz : letz@grame.fr Need a fix : this crash on MacOSX : temporary removed jack_release_shm (&client->port_segment[ptid]); */ #else jack_release_shm (&client->port_segment[ptid]); #endif } /* get the index into the shm registry */ client->port_segment[ptid].index = client->engine->port_types[ptid].shm_registry_index; /* attach the relevant segment */ if (jack_attach_shm (&client->port_segment[ptid])) { jack_error ("cannot attach port segment shared memory" " (%s)", strerror (errno)); return -1; } /* The first chunk of the audio port segment will be set by * the engine to be a zero-filled buffer. This hasn't been * done yet, but it will happen before the process cycle * (re)starts. */ if (ptid == JACK_AUDIO_PORT_TYPE) { jack_zero_filled_buffer = jack_shm_addr (&client->port_segment[ptid]); } return 0; } jack_client_t * jack_client_open (const char *client_name, jack_options_t options, jack_status_t *status, const char *server_name, const char *server_command) { int req_fd = -1; int ev_fd = -1; jack_client_connect_result_t res; jack_client_t *client; jack_port_type_id_t ptid; jack_status_t my_status; if (status == NULL) /* no status from caller? */ status = &my_status; /* use local status word */ *status = 0; /* External clients need this initialized. It is already set * up in the server's address space for internal clients. */ jack_init_time (); if (jack_initialize_shm ()) { jack_error ("Unable to initialize shared memory."); return NULL; } if (jack_request_client (ClientExternal, client_name, "", "", &res, &req_fd, options, status, server_name, server_command)) { return NULL; } client = jack_client_alloc (); strcpy (client->name, res.name); strcpy (client->fifo_prefix, res.fifo_prefix); client->request_fd = req_fd; client->pollfd[EVENT_POLL_INDEX].events = POLLIN|POLLERR|POLLHUP|POLLNVAL; client->pollfd[WAIT_POLL_INDEX].events = POLLIN|POLLERR|POLLHUP|POLLNVAL; /* attach the engine control/info block */ client->engine_shm = res.engine_shm; if (jack_attach_shm (&client->engine_shm)) { jack_error ("cannot attached engine control shared memory" " segment"); goto fail; } client->engine = (jack_control_t *) jack_shm_addr (&client->engine_shm); /* now attach the client control block */ client->control_shm = res.client_shm; if (jack_attach_shm (&client->control_shm)) { jack_error ("cannot attached client control shared memory" " segment"); goto fail; } client->control = (jack_client_control_t *) jack_shm_addr (&client->control_shm); /* nobody else needs to access this shared memory any more, so destroy it. because we have our own attachment to it, it won't vanish till we exit (and release it). */ jack_destroy_shm (&client->control_shm); client->n_port_types = client->engine->n_port_types; client->port_segment = (jack_shm_info_t *) malloc (sizeof (jack_shm_info_t) * client->n_port_types); for (ptid = 0; ptid < client->n_port_types; ++ptid) { client->port_segment[ptid].index = client->engine->port_types[ptid].shm_registry_index; client->port_segment[ptid].attached_at = MAP_FAILED; jack_attach_port_segment (client, ptid); } /* set up the client so that it does the right thing for an * external client */ client->control->deliver_request = oop_client_deliver_request; client->control->deliver_arg = client; if ((ev_fd = server_event_connect (client)) < 0) { goto fail; } client->event_fd = ev_fd; #ifdef JACK_USE_MACH_THREADS /* specific resources for server/client real-time thread * communication */ client->clienttask = mach_task_self(); if (task_get_bootstrap_port(client->clienttask, &client->bp)){ jack_error ("Can't find bootstrap port"); goto fail; } if (allocate_mach_clientport(client, res.portnum) < 0) { jack_error("Can't allocate mach port"); goto fail; }; #endif /* JACK_USE_MACH_THREADS */ return client; fail: if (client->engine) { jack_release_shm (&client->engine_shm); client->engine = 0; } if (client->control) { jack_release_shm (&client->control_shm); client->control = 0; } if (req_fd >= 0) { close (req_fd); } if (ev_fd >= 0) { close (ev_fd); } return 0; } jack_client_t * jack_client_new (const char *client_name) { jack_options_t options = JackUseExactName; if (getenv("JACK_START_SERVER") == NULL) options |= JackNoStartServer; return jack_client_open (client_name, options, NULL, NULL, NULL); } char * jack_get_client_name (jack_client_t *client) { return client->name; } int jack_internal_client_new (const char *client_name, const char *so_name, const char *so_data) { jack_client_connect_result_t res; int req_fd; jack_status_t status; return jack_request_client (ClientInternal, client_name, so_name, so_data, &res, &req_fd, 0, &status, NULL, NULL); } void jack_internal_client_close (const char *client_name) { jack_client_connect_request_t req; int fd; req.load = FALSE; snprintf (req.name, sizeof (req.name), "%s", client_name); if ((fd = server_connect (NULL)) < 0) { return; } if (write (fd, &req, sizeof (req)) != sizeof(req)) { jack_error ("cannot deliver ClientUnload request to JACK server."); } /* no response to this request */ close (fd); return; } int jack_set_freewheel (jack_client_t* client, int onoff) { jack_request_t request; request.type = onoff ? FreeWheel : StopFreeWheel; return jack_client_deliver_request (client, &request); } void jack_start_freewheel (jack_client_t* client) { jack_client_control_t *control = client->control; if (client->engine->real_time) { #if JACK_USE_MACH_THREADS jack_drop_real_time_scheduling (client->process_thread); #else jack_drop_real_time_scheduling (client->thread); #endif } if (control->freewheel_cb) { control->freewheel_cb (1, control->freewheel_arg); } } void jack_stop_freewheel (jack_client_t* client) { jack_client_control_t *control = client->control; if (control->freewheel_cb) { control->freewheel_cb (0, control->freewheel_arg); } if (client->engine->real_time) { #if JACK_USE_MACH_THREADS jack_acquire_real_time_scheduling (client->process_thread, client->engine->client_priority); #else jack_acquire_real_time_scheduling (client->thread, client->engine->client_priority); #endif } } static void * jack_client_thread (void *arg) { jack_client_t *client = (jack_client_t *) arg; jack_client_control_t *control = client->control; jack_event_t event; char status = 0; char c = 0; int err = 0; pthread_mutex_lock (&client_lock); client->thread_ok = TRUE; client->thread_id = pthread_self(); pthread_cond_signal (&client_ready); pthread_mutex_unlock (&client_lock); client->control->pid = getpid(); client->control->pgrp = getpgrp(); DEBUG ("client thread is now running"); if (client->control->thread_init) { DEBUG ("calling client thread init callback"); client->control->thread_init (client->control->thread_init_arg); } while (err == 0) { if (client->engine->engine_ok == 0) { if (client->on_shutdown) client->on_shutdown (client->on_shutdown_arg); else jack_error ("engine unexpectedly shutdown; " "thread exiting\n"); pthread_exit (0); } DEBUG ("client polling on %s", client->pollmax == 2 ? "event_fd and graph_wait_fd..." : "event_fd only"); if (poll (client->pollfd, client->pollmax, 1000) < 0) { if (errno == EINTR) { continue; } jack_error ("poll failed in client (%s)", strerror (errno)); status = -1; break; } /* get an accurate timestamp on waking from poll for a * process() cycle. */ if (client->graph_wait_fd >= 0 && client->pollfd[WAIT_POLL_INDEX].revents & POLLIN) { control->awake_at = jack_get_microseconds(); } DEBUG ("pfd[EVENT].revents = 0x%x pfd[WAIT].revents = 0x%x", client->pollfd[EVENT_POLL_INDEX].revents, client->pollfd[WAIT_POLL_INDEX].revents); pthread_testcancel(); if (client->graph_wait_fd >= 0 && (client->pollfd[WAIT_POLL_INDEX].revents & ~POLLIN)) { DEBUG ("\n\n\n\n\n\n\n\nWAITFD ERROR, ZOMBIE\n\n\n\n\n"); /* our upstream "wait" connection closed, which either means that an intermediate client exited, or jackd exited, or jackd zombified us. we can discover the zombification via client->control->dead, but the other two possibilities are impossible to identify just from this situation. so we have to check what we are connected to, and act accordingly. */ if (client->upstream_is_jackd) { DEBUG ("WE DIE\n"); goto zombie; } else { DEBUG ("WE PUNT\n"); /* don't poll on the wait fd * again until we get a * GraphReordered event. */ client->graph_wait_fd = -1; client->pollmax = 1; } } if (client->control->dead) { goto zombie; } if (client->pollfd[EVENT_POLL_INDEX].revents & ~POLLIN) { /* jackd shutdown */ goto zombie; } if (client->pollfd[EVENT_POLL_INDEX].revents & POLLIN) { DEBUG ("client receives an event, " "now reading on event fd"); /* server has sent us an event. process the * event and reply */ if (read (client->event_fd, &event, sizeof (event)) != sizeof (event)) { jack_error ("cannot read server event (%s)", strerror (errno)); err++; break; } status = 0; switch (event.type) { case PortRegistered: if (control->port_register) { control->port_register (event.x.port_id, TRUE, control->port_register_arg); } break; case PortUnregistered: if (control->port_register) { control->port_register (event.x.port_id, FALSE, control->port_register_arg); } break; case GraphReordered: status = jack_handle_reorder (client, &event); break; case PortConnected: case PortDisconnected: status = jack_client_handle_port_connection (client, &event); break; case BufferSizeChange: jack_client_invalidate_port_buffers (client); if (control->bufsize) { status = control->bufsize (control->nframes, control->bufsize_arg); } break; case SampleRateChange: if (control->srate) { status = control->srate (control->nframes, control->srate_arg); } break; case XRun: if (control->xrun) { status = control->xrun (control->xrun_arg); } break; case AttachPortSegment: jack_attach_port_segment (client, event.y.ptid); break; case StartFreewheel: jack_start_freewheel (client); break; case StopFreewheel: jack_stop_freewheel (client); break; } DEBUG ("client has dealt with the event, writing " "response on event fd"); if (write (client->event_fd, &status, sizeof (status)) != sizeof (status)) { jack_error ("cannot send event response to " "engine (%s)", strerror (errno)); err++; break; } } if (client->pollfd[WAIT_POLL_INDEX].revents & POLLIN) { #ifdef WITH_TIMESTAMPS jack_reset_timestamps (); #endif DEBUG ("client %d signalled at %" PRIu64 ", awake for process at %" PRIu64 " (delay = %" PRIu64 " usecs) (wakeup on graph_wait_fd==%d)", getpid(), control->signalled_at, control->awake_at, control->awake_at - control->signalled_at, client->pollfd[WAIT_POLL_INDEX].fd); control->state = Running; if (control->sync_cb) jack_call_sync_client (client); if (control->process) { if (control->process (control->nframes, control->process_arg) == 0) { control->state = Finished; } } else { control->state = Finished; } if (control->timebase_cb) jack_call_timebase_master (client); control->finished_at = jack_get_microseconds(); #ifdef WITH_TIMESTAMPS jack_timestamp ("finished"); #endif /* pass the execution token along */ DEBUG ("client finished processing at %" PRIu64 " (elapsed = %" PRIu64 " usecs), writing on graph_next_fd==%d", control->finished_at, control->finished_at - control->awake_at, client->graph_next_fd); if (write (client->graph_next_fd, &c, sizeof (c)) != sizeof (c)) { jack_error ("cannot continue execution of the " "processing graph (%s)", strerror(errno)); err++; break; } DEBUG ("client sent message to next stage by %" PRIu64 ", client reading on graph_wait_fd==%d", jack_get_microseconds(), client->graph_wait_fd); #ifdef WITH_TIMESTAMPS jack_timestamp ("read pending byte from wait"); #endif DEBUG("reading cleanup byte from pipe\n"); if ((read (client->graph_wait_fd, &c, sizeof (c)) != sizeof (c))) { DEBUG ("WARNING: READ FAILED!"); #if 0 jack_error ("cannot complete execution of the " "processing graph (%s)", strerror(errno)); err++; break; #endif } /* check if we were killed during the process * cycle (or whatever) */ if (client->control->dead) { goto zombie; } DEBUG("process cycle fully complete\n"); #ifdef WITH_TIMESTAMPS jack_timestamp ("read done"); jack_dump_timestamps (stdout); #endif } } return (void *) ((intptr_t)err); zombie: if (client->on_shutdown) { jack_error ("zombified - calling shutdown handler"); client->on_shutdown (client->on_shutdown_arg); } else { jack_error ("zombified - exiting from JACK"); jack_client_close (client); /* Need a fix : possibly make client crash if * zombified without shutdown handler */ } pthread_exit (0); /*NOTREACHED*/ return 0; } #ifdef JACK_USE_MACH_THREADS /* real-time thread : separated from the normal client thread, it will * communicate with the server using fast mach RPC mechanism */ static void * jack_client_process_thread (void *arg) { jack_client_t *client = (jack_client_t *) arg; jack_client_control_t *control = client->control; int err = 0; if (client->control->thread_init) { /* this means that the init callback will be called twice -taybin*/ DEBUG ("calling client thread init callback"); client->control->thread_init (client->control->thread_init_arg); } client->control->pid = getpid(); DEBUG ("client process thread is now running"); client->rt_thread_ok = TRUE; while (err == 0) { if (jack_client_suspend(client) < 0) { jack_error ("jack_client_process_thread : resume error"); goto zombie; } control->awake_at = jack_get_microseconds(); DEBUG ("client resumed"); control->state = Running; if (control->sync_cb) jack_call_sync_client (client); if (control->process) { if (control->process (control->nframes, control->process_arg) == 0) { control->state = Finished; } } else { control->state = Finished; } if (control->timebase_cb) jack_call_timebase_master (client); control->finished_at = jack_get_microseconds(); #ifdef WITH_TIMESTAMPS jack_timestamp ("finished"); #endif DEBUG ("client finished processing at %Lu (elapsed = %f usecs)", control->finished_at, ((float)(control->finished_at - control->awake_at))); /* check if we were killed during the process cycle (or whatever) */ if (client->control->dead) { jack_error ("jack_client_process_thread : client->control->dead"); goto zombie; } DEBUG("process cycle fully complete\n"); } return (void *) ((intptr_t)err); zombie: jack_error ("jack_client_process_thread : zombified"); client->rt_thread_ok = FALSE; if (client->on_shutdown) { jack_error ("zombified - calling shutdown handler"); client->on_shutdown (client->on_shutdown_arg); } else { jack_error ("zombified - exiting from JACK"); jack_client_close (client); /* Need a fix : possibly make client crash if zombified without shutdown handler */ } pthread_exit (0); /*NOTREACHED*/ return 0; } #endif /* JACK_USE_MACH_THREADS */ static int jack_start_thread (jack_client_t *client) { if (client->engine->real_time) { #ifdef USE_MLOCK if (client->engine->do_mlock && (mlockall (MCL_CURRENT | MCL_FUTURE) != 0)) { jack_error ("cannot lock down memory for RT thread (%s)", strerror (errno)); #ifdef ENSURE_MLOCK return -1; #endif /* ENSURE_MLOCK */ } if (client->engine->do_munlock) { cleanup_mlock (); } #endif /* USE_MLOCK */ } #ifdef JACK_USE_MACH_THREADS /* Stephane Letz : letz@grame.fr On MacOSX, the normal thread does not need to be real-time. */ if (jack_create_thread (&client->thread, client->engine->client_priority, 0, jack_client_thread, client)) { return -1; } #else if (jack_create_thread (&client->thread, client->engine->client_priority, client->engine->real_time, jack_client_thread, client)) { return -1; } #endif #ifdef JACK_USE_MACH_THREADS /* a secondary thread that runs the process callback and uses ultra-fast Mach primitives for inter-thread signalling. XXX in a properly structured JACK, there would be no need for this, because we would have client wake up methods that encapsulated the underlying mechanism used. */ if (jack_create_thread(&client->process_thread, client->engine->client_priority, client->engine->real_time, jack_client_process_thread, client)) { return -1; } #endif /* JACK_USE_MACH_THREADS */ return 0; } int jack_activate (jack_client_t *client) { jack_request_t req; /* we need to scribble on our stack to ensure that its memory * pages are actually mapped (more important for mlockall(2) * usage in jack_start_thread()) */ char buf[JACK_THREAD_STACK_TOUCH]; int i; for (i = 0; i < JACK_THREAD_STACK_TOUCH; i++) { buf[i] = (char) (i & 0xff); } if (client->control->type == ClientInternal || client->control->type == ClientDriver) { goto startit; } /* get the pid of the client process to pass it to engine */ client->control->pid = getpid (); #ifdef USE_CAPABILITIES if (client->engine->has_capabilities != 0 && client->control->pid != 0 && client->engine->real_time != 0) { /* we need to ask the engine for realtime capabilities before trying to start the realtime thread */ req.type = SetClientCapabilities; req.x.client_id = client->control->id; jack_client_deliver_request (client, &req); if (req.status) { /* what to do? engine is running realtime, it is using capabilities and has them (otherwise we would not get an error return) but for some reason it could not give the client the required capabilities, so for now downgrade the client so that it still runs, albeit non-realtime - nando */ jack_error ("could not receive realtime capabilities, " "client will run non-realtime"); /* XXX wrong, this is a property of the engine client->engine->real_time = 0; */ } } #endif /* USE_CAPABILITIES */ if (client->first_active) { pthread_mutex_init (&client_lock, NULL); pthread_cond_init (&client_ready, NULL); pthread_mutex_lock (&client_lock); if (jack_start_thread (client)) { pthread_mutex_unlock (&client_lock); return -1; } pthread_cond_wait (&client_ready, &client_lock); pthread_mutex_unlock (&client_lock); if (!client->thread_ok) { jack_error ("could not start client thread"); return -1; } client->first_active = FALSE; } startit: req.type = ActivateClient; req.x.client_id = client->control->id; return jack_client_deliver_request (client, &req); } int jack_deactivate (jack_client_t *client) { jack_request_t req; req.type = DeactivateClient; req.x.client_id = client->control->id; return jack_client_deliver_request (client, &req); } int jack_client_close (jack_client_t *client) { JSList *node; void *status; if (client->control->active) { jack_deactivate (client); } if (client->control->type == ClientExternal) { #if JACK_USE_MACH_THREADS if (client->rt_thread_ok) { // MacOSX pthread_cancel not implemented in // Darwin 5.5, 6.4 mach_port_t machThread = pthread_mach_thread_np (client->process_thread); thread_terminate (machThread); } #endif /* stop the thread that communicates with the jack * server, only if it was actually running */ if (client->thread_ok){ pthread_cancel (client->thread); pthread_join (client->thread, &status); } if (client->control) { jack_release_shm (&client->control_shm); client->control = NULL; } if (client->engine) { jack_release_shm (&client->engine_shm); client->engine = NULL; } if (client->port_segment) { jack_port_type_id_t ptid; for (ptid = 0; ptid < client->n_port_types; ++ptid) { jack_release_shm (&client->port_segment[ptid]); } free (client->port_segment); client->port_segment = NULL; } if (client->graph_wait_fd) { close (client->graph_wait_fd); } if (client->graph_next_fd) { close (client->graph_next_fd); } close (client->event_fd); close (client->request_fd); } for (node = client->ports; node; node = jack_slist_next (node)) { free (node->data); } jack_slist_free (client->ports); jack_client_free (client); return 0; } int jack_is_realtime (jack_client_t *client) { return client->engine->real_time; } jack_nframes_t jack_get_buffer_size (jack_client_t *client) { return client->engine->buffer_size; } int jack_set_buffer_size (jack_client_t *client, jack_nframes_t nframes) { #ifdef DO_BUFFER_RESIZE jack_request_t req; req.type = SetBufferSize; req.x.nframes = nframes; return jack_client_deliver_request (client, &req); #else return ENOSYS; #endif /* DO_BUFFER_RESIZE */ } int jack_connect (jack_client_t *client, const char *source_port, const char *destination_port) { jack_request_t req; req.type = ConnectPorts; snprintf (req.x.connect.source_port, sizeof (req.x.connect.source_port), "%s", source_port); snprintf (req.x.connect.destination_port, sizeof (req.x.connect.destination_port), "%s", destination_port); return jack_client_deliver_request (client, &req); } int jack_port_disconnect (jack_client_t *client, jack_port_t *port) { jack_request_t req; pthread_mutex_lock (&port->connection_lock); if (port->connections == NULL) { pthread_mutex_unlock (&port->connection_lock); return 0; } pthread_mutex_unlock (&port->connection_lock); req.type = DisconnectPort; req.x.port_info.port_id = port->shared->id; return jack_client_deliver_request (client, &req); } int jack_disconnect (jack_client_t *client, const char *source_port, const char *destination_port) { jack_request_t req; req.type = DisconnectPorts; snprintf (req.x.connect.source_port, sizeof (req.x.connect.source_port), "%s", source_port); snprintf (req.x.connect.destination_port, sizeof (req.x.connect.destination_port), "%s", destination_port); return jack_client_deliver_request (client, &req); } void jack_set_error_function (void (*func) (const char *)) { jack_error_callback = func; } int jack_set_graph_order_callback (jack_client_t *client, JackGraphOrderCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->graph_order = callback; client->control->graph_order_arg = arg; return 0; } int jack_set_xrun_callback (jack_client_t *client, JackXRunCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->xrun = callback; client->control->xrun_arg = arg; return 0; } int jack_set_process_callback (jack_client_t *client, JackProcessCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->process_arg = arg; client->control->process = callback; return 0; } int jack_set_thread_init_callback (jack_client_t *client, JackThreadInitCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->thread_init_arg = arg; client->control->thread_init = callback; return 0; } int jack_set_freewheel_callback (jack_client_t *client, JackFreewheelCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->freewheel_arg = arg; client->control->freewheel_cb = callback; return 0; } int jack_set_buffer_size_callback (jack_client_t *client, JackBufferSizeCallback callback, void *arg) { client->control->bufsize_arg = arg; client->control->bufsize = callback; return 0; } int jack_set_port_registration_callback(jack_client_t *client, JackPortRegistrationCallback callback, void *arg) { if (client->control->active) { jack_error ("You cannot set callbacks on an active client."); return -1; } client->control->port_register_arg = arg; client->control->port_register = callback; return 0; } int jack_get_process_done_fd (jack_client_t *client) { return client->graph_next_fd; } void jack_on_shutdown (jack_client_t *client, void (*function)(void *arg), void *arg) { client->on_shutdown = function; client->on_shutdown_arg = arg; } const char ** jack_get_ports (jack_client_t *client, const char *port_name_pattern, const char *type_name_pattern, unsigned long flags) { jack_control_t *engine; const char **matching_ports; unsigned long match_cnt; jack_port_shared_t *psp; unsigned long i; regex_t port_regex; regex_t type_regex; int matching; engine = client->engine; if (port_name_pattern && port_name_pattern[0]) { regcomp (&port_regex, port_name_pattern, REG_EXTENDED|REG_NOSUB); } if (type_name_pattern && type_name_pattern[0]) { regcomp (&type_regex, type_name_pattern, REG_EXTENDED|REG_NOSUB); } psp = engine->ports; match_cnt = 0; matching_ports = (const char **) malloc (sizeof (char *) * engine->port_max); for (i = 0; i < engine->port_max; i++) { matching = 1; if (!psp[i].in_use) { continue; } if (flags) { if ((psp[i].flags & flags) != flags) { matching = 0; } } if (matching && port_name_pattern && port_name_pattern[0]) { if (regexec (&port_regex, psp[i].name, 0, NULL, 0)) { matching = 0; } } if (matching && type_name_pattern && type_name_pattern[0]) { jack_port_type_id_t ptid = psp[i].ptype_id; if (regexec (&type_regex, engine->port_types[ptid].type_name, 0, NULL, 0)) { matching = 0; } } if (matching) { matching_ports[match_cnt++] = psp[i].name; } } if (port_name_pattern && port_name_pattern[0]) { regfree (&port_regex); } if (type_name_pattern && type_name_pattern[0]) { regfree (&type_regex); } matching_ports[match_cnt] = 0; if (match_cnt == 0) { free (matching_ports); matching_ports = 0; } return matching_ports; } float jack_cpu_load (jack_client_t *client) { return client->engine->cpu_load; } float jack_get_xrun_delayed_usecs (jack_client_t *client) { return client->engine->xrun_delayed_usecs; } pthread_t jack_client_thread_id (jack_client_t *client) { return client->thread_id; } int jack_client_name_size(void) { return JACK_CLIENT_NAME_SIZE; } int jack_port_name_size(void) { return JACK_PORT_NAME_SIZE; } int jack_port_type_size(void) { return JACK_PORT_TYPE_SIZE; }