/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Event Ports can be shared across threads or across processes. * Every thread/process can use an own event port or a group of them * can use a single port. A major request was also to get the ability * to submit user-defined events to a port. The idea of the * user-defined events is to use the event ports for communication between * threads/processes (like message queues). User defined-events are queued * in a port with the same priority as other event types. * * Events are delivered only once. The thread/process which is waiting * for events with the "highest priority" (priority here is related to the * internal strategy to wakeup waiting threads) will retrieve the event, * all other threads/processes will not be notified. There is also * the requirement to have events which should be submitted immediately * to all "waiting" threads. That is the main task of the alert event. * The alert event is submitted by the application to a port. The port * changes from a standard mode to the alert mode. Now all waiting threads * will be awaken immediately and they will return with the alert event. * Threads trying to retrieve events from a port in alert mode will * return immediately with the alert event. * * * An event port is like a kernel queue, which accept events submitted from * user level as well as events submitted from kernel sub-systems. Sub-systems * able to submit events to a port are the so-called "event sources". * Current event sources: * PORT_SOURCE_AIO : events submitted per transaction completion from * POSIX-I/O framework. * PORT_SOURCE_TIMER : events submitted when a timer fires * (see timer_create(3RT)). * PORT_SOURCE_FD : events submitted per file descriptor (see poll(2)). * PORT_SOURCE_ALERT : events submitted from user. This is not really a * single event, this is actually a port mode * (see port_alert(3c)). * PORT_SOURCE_USER : events submitted by applications with * port_send(3c) or port_sendn(3c). * * There is a user API implemented in the libc library as well as a * kernel API implemented in port_subr.c in genunix. * The available user API functions are: * port_create() : create a port as a file descriptor of portfs file system * The standard close(2) function closes a port. * port_associate() : associate a file descriptor with a port to be able to * retrieve events from that file descriptor. * port_dissociate(): remove the association of a file descriptor with a port. * port_alert() : set/unset a port in alert mode * port_send() : send an event of type PORT_SOURCE_USER to a port * port_sendn() : send an event of type PORT_SOURCE_USER to a list of ports * port_get() : retrieve a single event from a port * port_getn() : retrieve a list of events from a port * * The available kernel API functions are: * port_allocate_event(): allocate an event slot/structure of/from a port * port_init_event() : set event data in the event structure * port_send_event() : send event to a port * port_free_event() : deliver allocated slot/structure back to a port * port_associate_ksource(): associate a kernel event source with a port * port_dissociate_ksource(): dissociate a kernel event source from a port * * The libc implementation consists of small functions which pass the * arguments to the kernel using the "portfs" system call. It means, all the * synchronisation work is being done in the kernel. The "portfs" system * call loads the portfs file system into the kernel. * * PORT CREATION * The first function to be used is port_create() which internally creates * a vnode and a portfs node. The portfs node is represented by the port_t * structure, which again includes all the data necessary to control a port. * port_create() returns a file descriptor, which needs to be used in almost * all other event port functions. * The maximum number of ports per system is controlled by the resource * control: project:port-max-ids. * * EVENT GENERATION * The second step is the triggering of events, which could be sent to a port. * Every event source implements an own method to generate events for a port: * PORT_SOURCE_AIO: * The sigevent structure of the standard POSIX-IO functions * was extended by an additional notification type. * Standard notification types: * SIGEV_NONE, SIGEV_SIGNAL and SIGEV_THREAD * Event ports introduced now SIGEV_PORT. * The notification type SIGEV_PORT specifies that a structure * of type port_notify_t has to be attached to the sigev_value. * The port_notify_t structure contains the event port file * descriptor and a user-defined pointer. * Internally the AIO implementation will use the kernel API * functions to allocate an event port slot per transaction (aiocb) * and sent the event to the port as soon as the transaction completes. * All the events submitted per transaction are of type * PORT_SOURCE_AIO. * PORT_SOURCE_TIMER: * The timer_create() function uses the same method as the * PORT_SOURCE_AIO event source. It also uses the sigevent structure * to deliver the port information. * Internally the timer code will allocate a single event slot/struct * per timer and it will send the timer event as soon as the timer * fires. If the timer-fired event is not delivered to the application * before the next period elapsed, then an overrun counter will be * incremented. The timer event source uses a callback function to * detect the delivery of the event to the application. At that time * the timer callback function will update the event overrun counter. * PORT_SOURCE_FD: * This event source uses the port_associate() function to allocate * an event slot/struct from a port. The application defines in the * events argument of port_associate() the type of events which it is * interested on. * The internal pollwakeup() function is used by all the file * systems --which are supporting the VOP_POLL() interface- to notify * the upper layer (poll(2), devpoll(7d) and now event ports) about * the event triggered (see valid events in poll(2)). * The pollwakeup() function forwards the event to the layer registered * to receive the current event. * The port_dissociate() function can be used to free the allocated * event slot from the port. Anyway, file descriptors deliver events * only one time and remain deactivated until the application * reactivates the association of a file descriptor with port_associate(). * If an associated file descriptor is closed then the file descriptor * will be dissociated automatically from the port. * * PORT_SOURCE_ALERT: * This event type is generated when the port was previously set in * alert mode using the port_alert() function. * A single alert event is delivered to every thread which tries to * retrieve events from a port. * PORT_SOURCE_USER: * This type of event is generated from user level using the port_send() * function to send a user event to a port or the port_sendn() function * to send an event to a list of ports. * * EVENT DELIVERY / RETRIEVING EVENTS * Events remain in the port queue until: * - the application uses port_get() or port_getn() to retrieve events, * - the event source cancel the event, * - the event port is closed or * - the process exits. * The maximal number of events in a port queue is the maximal number * of event slots/structures which can be allocated by event sources. * The allocation of event slots/structures is controlled by the resource * control: process.port-max-events. * The port_get() function retrieves a single event and the port_getn() * function retrieves a list of events. * Events are classified as shareable and non-shareable events across processes. * Non-shareable events are invisible for the port_get(n)() functions of * processes other than the owner of the event. * Shareable event types are: * PORT_SOURCE_USER events * This type of event is unconditionally shareable and without * limitations. If the parent process sends a user event and closes * the port afterwards, the event remains in the port and the child * process will still be able to retrieve the user event. * PORT_SOURCE_ALERT events * This type of event is shareable between processes. * Limitation: The alert mode of the port is removed if the owner * (process which set the port in alert mode) of the * alert event closes the port. * PORT_SOURCE_FD events * This type of event is conditional shareable between processes. * After fork(2) all forked file descriptors are shareable between * the processes. The child process is allowed to retrieve events * from the associated file descriptors and it can also re-associate * the fd with the port. * Limitations: The child process is not allowed to dissociate * the file descriptor from the port. Only the * owner (process) of the association is allowed to * dissociate the file descriptor from the port. * If the owner of the association closes the port * the association will be removed. * PORT_SOURCE_AIO events * This type of event is not shareable between processes. * PORT_SOURCE_TIMER events * This type of event is not shareable between processes. * * FORK BEHAVIOUR * On fork(2) the child process inherits all opened file descriptors from * the parent process. This is also valid for port file descriptors. * Associated file descriptors with a port maintain the association across the * fork(2). It means, the child process gets full access to the port and * it can retrieve events from all common associated file descriptors. * Events of file descriptors created and associated with a port after the * fork(2) are non-shareable and can only be retrieved by the same process. * * If the parent or the child process closes an exported port (using fork(2) * or I_SENDFD) all the file descriptors associated with the port by the * process will be dissociated from the port. Events of dissociated file * descriptors as well as all non-shareable events will be discarded. * The other process can continue working with the port as usual. * * CLOSING A PORT * close(2) has to be used to close a port. See FORK BEHAVIOUR for details. * * PORT EVENT STRUCTURES * The global control structure of the event ports framework is port_control_t. * port_control_t keeps track of the number of created ports in the system. * The cache of the port event structures is also located in port_control_t. * * On port_create() the vnode and the portfs node is also created. * The portfs node is represented by the port_t structure. * The port_t structure manages all port specific tasks: * - management of resource control values * - port VOP_POLL interface * - creation time * - uid and gid of the port * * The port_t structure contains the port_queue_t structure. * The port_queue_t structure contains all the data necessary for the * queue management: * - locking * - condition variables * - event counters * - submitted events (represented by port_kevent_t structures) * - threads waiting for event delivery (check portget_t structure) * - PORT_SOURCE_FD cache (managed by the port_fdcache_t structure) * - event source management (managed by the port_source_t structure) * - alert mode management (check port_alert_t structure) * * EVENT MANAGEMENT * The event port file system creates a kmem_cache for internal allocation of * event port structures. * * 1. Event source association with a port: * The first step to do for event sources is to get associated with a port * using the port_associate_ksource() function or adding an entry to the * port_ksource_tab[]. An event source can get dissociated from a port * using the port_dissociate_ksource() function. An entry in the * port_ksource_tab[] implies that the source will be associated * automatically with every new created port. * The event source can deliver a callback function, which is used by the * port to notify the event source about close(2). The idea is that * in such a case the event source should free all allocated resources * and it must return to the port all allocated slots/structures. * The port_close() function will wait until all allocated event * structures/slots are returned to the port. * The callback function is not necessary when the event source does not * maintain local resources, a second condition is that the event source * can guarantee that allocated event slots will be returned without * delay to the port (it will not block and sleep somewhere). * * 2. Reservation of an event slot / event structure * The event port reliability is based on the reservation of an event "slot" * (allocation of an event structure) by the event source as part of the * application call. If the maximal number of event slots is exhausted then * the event source can return a corresponding error code to the application. * * The port_alloc_event() function has to be used by event sources to * allocate an event slot (reserve an event structure). The port_alloc_event() * doesn not block and it will return a 0 value on success or an error code * if it fails. * An argument of port_alloc_event() is a flag which determines the behavior * of the event after it was delivered to the application: * PORT_ALLOC_DEFAULT : event slot becomes free after delivery to the * application. * PORT_ALLOC_PRIVATE : event slot remains under the control of the event * source. This kind of slots can not be used for * event delivery and should only be used internally * by the event source. * PORT_KEV_CACHED : event slot remains under the control of an event * port cache. It does not become free after delivery * to the application. * PORT_ALLOC_SCACHED : event slot remains under the control of the event * source. The event source takes the control over * the slot after the event is delivered to the * application. * * 3. Delivery of events to the event port * Earlier allocated event structure/slot has to be used to deliver * event data to the port. Event source has to use the function * port_send_event(). The single argument is a pointer to the previously * reserved event structure/slot. * The portkev_events field of the port_kevent_t structure can be updated/set * in two ways: * 1. using the port_set_event() function, or * 2. updating the portkev_events field out of the callback function: * The event source can deliver a callback function to the port as an * argument of port_init_event(). * One of the arguments of the callback function is a pointer to the * events field, which will be delivered to the application. * (see Delivery of events to the application). * Event structures/slots can be delivered to the event port only one time, * they remain blocked until the data is delivered to the application and the * slot becomes free or it is delivered back to the event source * (PORT_ALLOC_SCACHED). The activation of the callback function mentioned above * is at the same time the indicator for the event source that the event * structure/slot is free for reuse. * * 4. Delivery of events to the application * The events structures/slots delivered by event sources remain in the * port queue until they are retrieved by the application or the port * is closed (exit(2) also closes all opened file descriptors).. * The application uses port_get() or port_getn() to retrieve events from * a port. port_get() retrieves a single event structure/slot and port_getn() * retrieves a list of event structures/slots. * Both functions are able to poll for events and return immediately or they * can specify a timeout value. * Before the events are delivered to the application they are moved to a * second temporary internal queue. The idea is to avoid lock collisions or * contentions of the global queue lock. * The global queue lock is used every time when an event source delivers * new events to the port. * The port_get() and port_getn() functions * a) retrieve single events from the temporary queue, * b) prepare the data to be passed to the application memory, * c) activate the callback function of the event sources: * - to get the latest event data, * - the event source can free all allocated resources associated with the * current event, * - the event source can re-use the current event slot/structure * - the event source can deny the delivery of the event to the application * (e.g. because of the wrong process). * d) put the event back to the temporary queue if the event delivery was denied * e) repeat a) until d) as long as there are events in the queue and * there is enough user space available. * * The loop described above could block for a very long time the global mutex, * to avoid that a second mutex was introduced to synchronized concurrent * threads accessing the temporary queue. */ static int64_t portfs(int, uintptr_t, uintptr_t, uintptr_t, uintptr_t, uintptr_t); static struct sysent port_sysent = { 6, SE_ARGC | SE_64RVAL | SE_NOUNLOAD, (int (*)())portfs, }; static struct modlsys modlsys = { &mod_syscallops, "event ports", &port_sysent }; #ifdef _SYSCALL32_IMPL static int64_t portfs32(uint32_t arg1, int32_t arg2, uint32_t arg3, uint32_t arg4, uint32_t arg5, uint32_t arg6); static struct sysent port_sysent32 = { 6, SE_ARGC | SE_64RVAL | SE_NOUNLOAD, (int (*)())portfs32, }; static struct modlsys modlsys32 = { &mod_syscallops32, "32-bit event ports syscalls", &port_sysent32 }; #endif /* _SYSCALL32_IMPL */ static struct modlinkage modlinkage = { MODREV_1, &modlsys, #ifdef _SYSCALL32_IMPL &modlsys32, #endif NULL }; port_kstat_t port_kstat = { { "ports", KSTAT_DATA_UINT32 } }; dev_t portdev; struct vnodeops *port_vnodeops; struct vfs port_vfs; extern rctl_hndl_t rc_process_portev; extern rctl_hndl_t rc_project_portids; extern void aio_close_port(void *, int, pid_t, int); /* * This table contains a list of event sources which need a static * association with a port (every port). * The last NULL entry in the table is required to detect "end of table". */ struct port_ksource port_ksource_tab[] = { {PORT_SOURCE_AIO, aio_close_port, NULL, NULL}, {0, NULL, NULL, NULL} }; /* local functions */ static int port_getn(port_t *, port_event_t *, uint_t, uint_t *, port_gettimer_t *); static int port_sendn(int [], int [], uint_t, int, void *, uint_t *); static int port_alert(port_t *, int, int, void *); static int port_dispatch_event(port_t *, int, int, int, uintptr_t, void *); static int port_send(port_t *, int, int, void *); static int port_create(int *); static int port_get_alert(port_alert_t *, port_event_t *); static int port_copy_event(port_event_t *, port_kevent_t *, list_t *); static int *port_errorn(int *, int, int, int); static int port_noshare(void *, int *, pid_t, int, void *); static int port_get_timeout(timespec_t *, timespec_t *, timespec_t **, int *, int); static void port_init(port_t *); static void port_remove_alert(port_queue_t *); static void port_add_ksource_local(port_t *, port_ksource_t *); static void port_check_return_cond(port_queue_t *); static void port_dequeue_thread(port_queue_t *, portget_t *); static portget_t *port_queue_thread(port_queue_t *, uint_t); static void port_kstat_init(void); #ifdef _SYSCALL32_IMPL static int port_copy_event32(port_event32_t *, port_kevent_t *, list_t *); #endif int _init(void) { static const fs_operation_def_t port_vfsops_template[] = { NULL, NULL }; extern const fs_operation_def_t port_vnodeops_template[]; vfsops_t *port_vfsops; int error; major_t major; if ((major = getudev()) == (major_t)-1) return (ENXIO); portdev = makedevice(major, 0); /* Create a dummy vfs */ error = vfs_makefsops(port_vfsops_template, &port_vfsops); if (error) { cmn_err(CE_WARN, "port init: bad vfs ops"); return (error); } vfs_setops(&port_vfs, port_vfsops); port_vfs.vfs_flag = VFS_RDONLY; port_vfs.vfs_dev = portdev; vfs_make_fsid(&(port_vfs.vfs_fsid), portdev, 0); error = vn_make_ops("portfs", port_vnodeops_template, &port_vnodeops); if (error) { vfs_freevfsops(port_vfsops); cmn_err(CE_WARN, "port init: bad vnode ops"); return (error); } mutex_init(&port_control.pc_mutex, NULL, MUTEX_DEFAULT, NULL); port_control.pc_nents = 0; /* number of active ports */ /* create kmem_cache for port event structures */ port_control.pc_cache = kmem_cache_create("port_cache", sizeof (port_kevent_t), 0, NULL, NULL, NULL, NULL, NULL, 0); port_kstat_init(); /* init port kstats */ return (mod_install(&modlinkage)); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } /* * System call wrapper for all port related system calls from 32-bit programs. */ #ifdef _SYSCALL32_IMPL static int64_t portfs32(uint32_t opcode, int32_t a0, uint32_t a1, uint32_t a2, uint32_t a3, uint32_t a4) { int64_t error; switch (opcode & PORT_CODE_MASK) { case PORT_GET: error = portfs(PORT_GET, a0, a1, (int)a2, (int)a3, a4); break; case PORT_SENDN: error = portfs(opcode, (uint32_t)a0, a1, a2, a3, a4); break; default: error = portfs(opcode, a0, a1, a2, a3, a4); break; } return (error); } #endif /* _SYSCALL32_IMPL */ /* * System entry point for port functions. * a0 is a port file descriptor (except for PORT_SENDN and PORT_CREATE). * The libc uses PORT_SYS_NOPORT in functions which do not deliver a * port file descriptor as first argument. */ static int64_t portfs(int opcode, uintptr_t a0, uintptr_t a1, uintptr_t a2, uintptr_t a3, uintptr_t a4) { rval_t r; port_t *pp; int error = 0; uint_t nget; file_t *fp; port_gettimer_t port_timer; r.r_vals = 0; if (opcode & PORT_SYS_NOPORT) { opcode &= PORT_CODE_MASK; if (opcode == PORT_SENDN) { error = port_sendn((int *)a0, (int *)a1, (uint_t)a2, (int)a3, (void *)a4, (uint_t *)&r.r_val1); if (error && (error != EIO)) return ((int64_t)set_errno(error)); return (r.r_vals); } if (opcode == PORT_CREATE) { error = port_create(&r.r_val1); if (error) return ((int64_t)set_errno(error)); return (r.r_vals); } } /* opcodes using port as first argument (a0) */ if ((fp = getf((int)a0)) == NULL) return ((uintptr_t)set_errno(EBADF)); if (fp->f_vnode->v_type != VPORT) { releasef((int)a0); return ((uintptr_t)set_errno(EBADFD)); } pp = VTOEP(fp->f_vnode); switch (opcode & PORT_CODE_MASK) { case PORT_GET: { /* see PORT_GETN description */ struct timespec timeout; port_timer.pgt_flags = PORTGET_ONE; port_timer.pgt_loop = 0; port_timer.pgt_rqtp = NULL; if (a4 != NULL) { port_timer.pgt_timeout = &timeout; timeout.tv_sec = (time_t)a2; timeout.tv_nsec = (long)a3; } else { port_timer.pgt_timeout = NULL; } do { nget = 1; error = port_getn(pp, (port_event_t *)a1, 1, (uint_t *)&nget, &port_timer); } while (nget == 0 && error == 0 && port_timer.pgt_loop); break; } case PORT_GETN: { /* * port_getn() can only retrieve own or shareable events from * other processes. The port_getn() function remains in the * kernel until own or shareable events are available or the * timeout elapses. */ port_timer.pgt_flags = 0; port_timer.pgt_loop = 0; port_timer.pgt_rqtp = NULL; port_timer.pgt_timeout = (struct timespec *)a4; do { nget = a3; error = port_getn(pp, (port_event_t *)a1, (uint_t)a2, (uint_t *)&nget, &port_timer); } while (nget == 0 && error == 0 && port_timer.pgt_loop); r.r_val1 = nget; r.r_val2 = error; releasef((int)a0); if (error && error != ETIME) return ((int64_t)set_errno(error)); return (r.r_vals); } case PORT_ASSOCIATE: { /* currently only PORT_SOURCE_FD is implemented */ if ((int)a1 != PORT_SOURCE_FD) { error = EINVAL; break; } error = port_associate_fd(pp, (int)a1, (uintptr_t)a2, (int)a3, (void *)a4); break; } case PORT_SEND: { /* user-defined events */ error = port_send(pp, PORT_SOURCE_USER, (int)a1, (void *)a2); break; } case PORT_DISPATCH: { /* * library events, blocking * Only events of type PORT_SOURCE_AIO or PORT_SOURCE_MQ * are currently allowed. */ if ((int)a1 != PORT_SOURCE_AIO && (int)a1 != PORT_SOURCE_MQ) { error = EINVAL; break; } error = port_dispatch_event(pp, (int)opcode, (int)a1, (int)a2, (uintptr_t)a3, (void *)a4); break; } case PORT_DISSOCIATE: { /* currently only PORT_SOURCE_FD is implemented */ if ((int)a1 != PORT_SOURCE_FD) { error = EINVAL; break; } error = port_dissociate_fd(pp, (uintptr_t)a2); break; } case PORT_ALERT: { if ((int)a2) /* a2 = events */ error = port_alert(pp, (int)a1, (int)a2, (void *)a3); else port_remove_alert(&pp->port_queue); break; } default: error = EINVAL; break; } releasef((int)a0); if (error) return ((int64_t)set_errno(error)); return (r.r_vals); } /* * System call to create a port. * * The port_create() function creates a vnode of type VPORT per port. * The port control data is associated with the vnode as vnode private data. * The port_create() function returns an event port file descriptor. */ static int port_create(int *fdp) { port_t *pp; vnode_t *vp; struct file *fp; proc_t *p = curproc; /* initialize vnode and port private data */ pp = kmem_zalloc(sizeof (port_t), KM_SLEEP); pp->port_vnode = vn_alloc(KM_SLEEP); vp = EPTOV(pp); vn_setops(vp, port_vnodeops); vp->v_type = VPORT; vp->v_vfsp = &port_vfs; vp->v_data = (caddr_t)pp; mutex_enter(&port_control.pc_mutex); /* * Retrieve the maximal number of event ports allowed per system from * the resource control: project.port-max-ids. */ mutex_enter(&p->p_lock); if (rctl_test(rc_project_portids, p->p_task->tk_proj->kpj_rctls, p, port_control.pc_nents + 1, RCA_SAFE) & RCT_DENY) { mutex_exit(&p->p_lock); vn_free(vp); kmem_free(pp, sizeof (port_t)); mutex_exit(&port_control.pc_mutex); return (EAGAIN); } /* * Retrieve the maximal number of events allowed per port from * the resource control: process.port-max-events. */ pp->port_max_events = rctl_enforced_value(rc_process_portev, p->p_rctls, p); mutex_exit(&p->p_lock); /* allocate a new user file descriptor and a file structure */ if (falloc(vp, 0, &fp, fdp)) { /* * If the file table is full, free allocated resources. */ vn_free(vp); kmem_free(pp, sizeof (port_t)); mutex_exit(&port_control.pc_mutex); return (EMFILE); } mutex_exit(&fp->f_tlock); pp->port_fd = *fdp; port_control.pc_nents++; p->p_portcnt++; port_kstat.pks_ports.value.ui32++; mutex_exit(&port_control.pc_mutex); /* initializes port private data */ port_init(pp); /* set user file pointer */ setf(*fdp, fp); return (0); } /* * port_init() initializes event port specific data */ static void port_init(port_t *pp) { port_queue_t *portq; port_ksource_t *pks; mutex_init(&pp->port_mutex, NULL, MUTEX_DEFAULT, NULL); portq = &pp->port_queue; mutex_init(&portq->portq_mutex, NULL, MUTEX_DEFAULT, NULL); pp->port_flags |= PORT_INIT; /* * If it is not enough memory available to satisfy a user * request using a single port_getn() call then port_getn() * will reduce the size of the list to PORT_MAX_LIST. */ pp->port_max_list = port_max_list; /* Set timestamp entries required for fstat(2) requests */ gethrestime(&pp->port_ctime); pp->port_uid = crgetuid(curproc->p_cred); pp->port_gid = crgetgid(curproc->p_cred); /* initialize port queue structs */ list_create(&portq->portq_list, sizeof (port_kevent_t), offsetof(port_kevent_t, portkev_node)); list_create(&portq->portq_get_list, sizeof (port_kevent_t), offsetof(port_kevent_t, portkev_node)); portq->portq_flags = 0; pp->port_pid = curproc->p_pid; /* Allocate cache skeleton for PORT_SOURCE_FD events */ portq->portq_pcp = kmem_zalloc(sizeof (port_fdcache_t), KM_SLEEP); mutex_init(&portq->portq_pcp->pc_lock, NULL, MUTEX_DEFAULT, NULL); /* * Allocate cache skeleton for association of event sources. */ mutex_init(&portq->portq_source_mutex, NULL, MUTEX_DEFAULT, NULL); portq->portq_scache = kmem_zalloc( PORT_SCACHE_SIZE * sizeof (port_source_t *), KM_SLEEP); /* * pre-associate some kernel sources with this port. * The pre-association is required to create port_source_t * structures for object association. * Some sources can not get associated with a port before the first * object association is requested. Another reason to pre_associate * a particular source with a port is because of performance. */ for (pks = port_ksource_tab; pks->pks_source != 0; pks++) port_add_ksource_local(pp, pks); } /* * The port_add_ksource_local() function is being used to associate * event sources with every new port. * The event sources need to be added to port_ksource_tab[]. */ static void port_add_ksource_local(port_t *pp, port_ksource_t *pks) { port_source_t *pse; port_source_t **ps; mutex_enter(&pp->port_queue.portq_source_mutex); ps = &pp->port_queue.portq_scache[PORT_SHASH(pks->pks_source)]; for (pse = *ps; pse != NULL; pse = pse->portsrc_next) { if (pse->portsrc_source == pks->pks_source) break; } if (pse == NULL) { /* associate new source with the port */ pse = kmem_zalloc(sizeof (port_source_t), KM_SLEEP); pse->portsrc_source = pks->pks_source; pse->portsrc_close = pks->pks_close; pse->portsrc_closearg = pks->pks_closearg; pse->portsrc_cnt = 1; pks->pks_portsrc = pse; if (*ps != NULL) pse->portsrc_next = (*ps)->portsrc_next; *ps = pse; } mutex_exit(&pp->port_queue.portq_source_mutex); } /* * The port_send() function sends an event of type "source" to a * port. This function is non-blocking. An event can be sent to * a port as long as the number of events per port does not achieve the * maximal allowed number of events. The max. number of events per port is * defined by the resource control process.max-port-events. * This function is used by the port library function port_send() * and port_dispatch(). The port_send(3c) function is part of the * event ports API and submits events of type PORT_SOURCE_USER. The * port_dispatch() function is project private and it is used by library * functions to submit events of other types than PORT_SOURCE_USER * (e.g. PORT_SOURCE_AIO). */ static int port_send(port_t *pp, int source, int events, void *user) { port_kevent_t *pev; int error; error = port_alloc_event_local(pp, source, PORT_ALLOC_DEFAULT, &pev); if (error) return (error); pev->portkev_object = 0; pev->portkev_events = events; pev->portkev_user = user; pev->portkev_callback = NULL; pev->portkev_arg = NULL; pev->portkev_flags = 0; port_send_event(pev); return (0); } /* * The port_noshare() function returns 0 if the current event was generated * by the same process. Otherwise is returns a value other than 0 and the * event should not be delivered to the current processe. * The port_noshare() function is normally used by the port_dispatch() * function. The port_dispatch() function is project private and can only be * used within the event port project. * Currently the libaio uses the port_dispatch() function to deliver events * of types PORT_SOURCE_AIO. */ /* ARGSUSED */ static int port_noshare(void *arg, int *events, pid_t pid, int flag, void *evp) { if (flag == PORT_CALLBACK_DEFAULT && curproc->p_pid != pid) return (1); return (0); } /* * The port_dispatch_event() function is project private and it is used by * libraries involved in the project to deliver events to the port. * port_dispatch will sleep and wait for enough resources to satisfy the * request, if necessary. * The library can specify if the delivered event is shareable with other * processes (see PORT_SYS_NOSHARE flag). */ static int port_dispatch_event(port_t *pp, int opcode, int source, int events, uintptr_t object, void *user) { port_kevent_t *pev; int error; error = port_alloc_event_block(pp, source, PORT_ALLOC_DEFAULT, &pev); if (error) return (error); pev->portkev_object = object; pev->portkev_events = events; pev->portkev_user = user; pev->portkev_arg = NULL; if (opcode & PORT_SYS_NOSHARE) { pev->portkev_flags = PORT_KEV_NOSHARE; pev->portkev_callback = port_noshare; } else { pev->portkev_flags = 0; pev->portkev_callback = NULL; } port_send_event(pev); return (0); } /* * The port_sendn() function is the kernel implementation of the event * port API function port_sendn(3c). * This function is able to send an event to a list of event ports. */ static int port_sendn(int ports[], int errors[], uint_t nent, int events, void *user, uint_t *nget) { port_kevent_t *pev; int errorcnt = 0; int error = 0; int count; int port; int *plist; int *elist = NULL; file_t *fp; port_t *pp; if (nent == 0 || nent > port_max_list) return (EINVAL); plist = kmem_alloc(nent * sizeof (int), KM_SLEEP); if (copyin((void *)ports, plist, nent * sizeof (int))) { kmem_free(plist, nent * sizeof (int)); return (EFAULT); } /* * Scan the list for event port file descriptors and send the * attached user event data embedded in a event of type * PORT_SOURCE_USER to every event port in the list. * If a list entry is not a valid event port then the corresponding * error code will be stored in the errors[] list with the same * list offset as in the ports[] list. */ for (count = 0; count < nent; count++) { port = plist[count]; if ((fp = getf(port)) == NULL) { elist = port_errorn(elist, nent, EBADF, count); errorcnt++; continue; } pp = VTOEP(fp->f_vnode); if (fp->f_vnode->v_type != VPORT) { releasef(port); elist = port_errorn(elist, nent, EBADFD, count); errorcnt++; continue; } error = port_alloc_event_local(pp, PORT_SOURCE_USER, PORT_ALLOC_DEFAULT, &pev); if (error) { releasef(port); elist = port_errorn(elist, nent, error, count); errorcnt++; continue; } pev->portkev_object = 0; pev->portkev_events = events; pev->portkev_user = user; pev->portkev_callback = NULL; pev->portkev_arg = NULL; pev->portkev_flags = 0; port_send_event(pev); releasef(port); } if (errorcnt) { error = EIO; if (copyout(elist, (void *)errors, nent * sizeof (int))) error = EFAULT; kmem_free(elist, nent * sizeof (int)); } *nget = nent - errorcnt; kmem_free(plist, nent * sizeof (int)); return (error); } static int * port_errorn(int *elist, int nent, int error, int index) { if (elist == NULL) elist = kmem_zalloc(nent * sizeof (int), KM_SLEEP); elist[index] = error; return (elist); } /* * port_alert() * The port_alert() funcion is a high priority event and it is always set * on top of the queue. It is also delivered as single event. * flags: * - SET :overwrite current alert data * - UPDATE:set alert data or return EBUSY if alert mode is already set * * - set the ALERT flag * - wakeup all sleeping threads */ static int port_alert(port_t *pp, int flags, int events, void *user) { port_queue_t *portq; portget_t *pgetp; port_alert_t *pa; if ((flags & PORT_ALERT_INVALID) == PORT_ALERT_INVALID) return (EINVAL); portq = &pp->port_queue; pa = &portq->portq_alert; mutex_enter(&portq->portq_mutex); /* check alert conditions */ if (flags == PORT_ALERT_UPDATE) { if (portq->portq_flags & PORTQ_ALERT) { mutex_exit(&portq->portq_mutex); return (EBUSY); } } /* * Store alert data in the port to be delivered to threads * which are using port_get(n) to retrieve events. */ portq->portq_flags |= PORTQ_ALERT; pa->portal_events = events; /* alert info */ pa->portal_pid = curproc->p_pid; /* process owner */ pa->portal_object = 0; /* no object */ pa->portal_user = user; /* user alert data */ /* alert and deliver alert data to waiting threads */ pgetp = portq->portq_thread; if (pgetp == NULL) { /* no threads waiting for events */ mutex_exit(&portq->portq_mutex); return (0); } /* * Set waiting threads in alert mode (PORTGET_ALERT).. * Every thread waiting for events already allocated a portget_t * structure to sleep on. * The port alert arguments are stored in the portget_t structure. * The PORTGET_ALERT flag is set to indicate the thread to return * immediately with the alert event. */ do { if ((pgetp->portget_state & PORTGET_ALERT) == 0) { pa = &pgetp->portget_alert; pa->portal_events = events; pa->portal_object = 0; pa->portal_user = user; pgetp->portget_state |= PORTGET_ALERT; cv_signal(&pgetp->portget_cv); } } while ((pgetp = pgetp->portget_next) != portq->portq_thread); mutex_exit(&portq->portq_mutex); return (0); } /* * Clear alert state of the port */ static void port_remove_alert(port_queue_t *portq) { mutex_enter(&portq->portq_mutex); portq->portq_flags &= ~PORTQ_ALERT; mutex_exit(&portq->portq_mutex); } /* * The port_getn() function is used to retrieve events from a port. * * The port_getn() function returns immediately if there are enough events * available in the port to satisfy the request or if the port is in alert * mode (see port_alert(3c)). * The timeout argument of port_getn(3c) -which is embedded in the * port_gettimer_t structure- specifies if the system call should block or if it * should return immediately depending on the number of events available. * This function is internally used by port_getn(3c) as well as by * port_get(3c). */ static int port_getn(port_t *pp, port_event_t *uevp, uint_t max, uint_t *nget, port_gettimer_t *pgt) { port_queue_t *portq; port_kevent_t *pev; port_kevent_t *lev; int error = 0; uint_t nmax; uint_t nevents; uint_t eventsz; port_event_t *kevp; list_t *glist; uint_t tnent; int rval; int blocking = -1; int flag; timespec_t rqtime; timespec_t *rqtp = NULL; portget_t *pgetp; void *results; model_t model = get_udatamodel(); flag = pgt->pgt_flags; if (*nget > max && max > 0) return (EINVAL); portq = &pp->port_queue; mutex_enter(&portq->portq_mutex); if (max == 0) { /* * Return number of objects with events. * The port_block() call is required to synchronize this * thread with another possible thread, which could be * retrieving events from the port queue. */ port_block(portq); /* * Check if a second thread is currently retrieving events * and it is using the temporary event queue. */ if (portq->portq_tnent) { /* put remaining events back to the port queue */ port_push_eventq(portq); } *nget = portq->portq_nent; port_unblock(portq); mutex_exit(&portq->portq_mutex); return (0); } if (uevp == NULL) { mutex_exit(&portq->portq_mutex); return (EFAULT); } if (*nget == 0) { /* no events required */ mutex_exit(&portq->portq_mutex); return (0); } /* port is being closed ... */ if (portq->portq_flags & PORTQ_CLOSE) { mutex_exit(&portq->portq_mutex); return (EBADFD); } /* return immediately if port in alert mode */ if (portq->portq_flags & PORTQ_ALERT) { error = port_get_alert(&portq->portq_alert, uevp); if (error == 0) *nget = 1; mutex_exit(&portq->portq_mutex); return (error); } portq->portq_thrcnt++; /* * Now check if the completed events satisfy the * "wait" requirements of the current thread: */ if (pgt->pgt_loop) { /* * loop entry of same thread * pgt_loop is set when the current thread returns * prematurely from this function. That could happen * when a port is being shared between processes and * this thread could not find events to return. * It is not allowed to a thread to retrieve non-shareable * events generated in other processes. * PORTQ_WAIT_EVENTS is set when a thread already * checked the current event queue and no new events * are added to the queue. */ if (((portq->portq_flags & PORTQ_WAIT_EVENTS) == 0) && (portq->portq_nent >= *nget)) { /* some new events arrived ...check them */ goto portnowait; } rqtp = pgt->pgt_rqtp; pgt->pgt_flags |= PORTGET_WAIT_EVENTS; } else { /* check if enough events are available ... */ if (portq->portq_nent >= *nget) goto portnowait; /* * There are not enough events available to satisfy * the request, check timeout value and wait for * incoming events. */ error = port_get_timeout(pgt->pgt_timeout, &rqtime, &rqtp, &blocking, flag); if (error) { port_check_return_cond(portq); mutex_exit(&portq->portq_mutex); return (error); } if (blocking == 0) /* don't block, check fired events */ goto portnowait; if (rqtp != NULL) { timespec_t now; gethrestime(&now); timespecadd(rqtp, &now); } } /* enqueue thread in the list of waiting threads */ pgetp = port_queue_thread(portq, *nget); /* Wait here until return conditions met */ for (;;) { if (pgetp->portget_state & PORTGET_ALERT) { /* reap alert event and return */ error = port_get_alert(&pgetp->portget_alert, uevp); if (error) *nget = 0; else *nget = 1; port_dequeue_thread(&pp->port_queue, pgetp); portq->portq_thrcnt--; mutex_exit(&portq->portq_mutex); return (error); } /* * Check if some other thread is already retrieving * events (portq_getn > 0). */ if ((portq->portq_getn == 0) && ((portq)->portq_nent >= *nget) && (!((pgt)->pgt_flags & PORTGET_WAIT_EVENTS) || !((portq)->portq_flags & PORTQ_WAIT_EVENTS))) break; if (portq->portq_flags & PORTQ_CLOSE) { error = EBADFD; break; } rval = cv_waituntil_sig(&pgetp->portget_cv, &portq->portq_mutex, rqtp); if (rval <= 0) { error = (rval == 0) ? EINTR : ETIME; break; } } /* take thread out of the wait queue */ port_dequeue_thread(portq, pgetp); if (error != 0 && (error == EINTR || error == EBADFD || (error == ETIME && flag))) { /* return without events */ port_check_return_cond(portq); mutex_exit(&portq->portq_mutex); return (error); } portnowait: /* * Move port event queue to a temporary event queue . * New incoming events will be continue be posted to the event queue * and they will not be considered by the current thread. * The idea is to avoid lock contentions or an often locking/unlocking * of the port queue mutex. The contention and performance degradation * could happen because: * a) incoming events use the port queue mutex to enqueue new events and * b) before the event can be delivered to the application it is * necessary to notify the event sources about the event delivery. * Sometimes the event sources can require a long time to return and * the queue mutex would block incoming events. * During this time incoming events (port_send_event()) do not need * to awake threads waiting for events. Before the current thread * returns it will check the conditions to awake other waiting threads. */ portq->portq_getn++; /* number of threads retrieving events */ port_block(portq); /* block other threads here */ nmax = max < portq->portq_nent ? max : portq->portq_nent; if (portq->portq_tnent) { /* * Move remaining events from previous thread back to the * port event queue. */ port_push_eventq(portq); } /* move port event queue to a temporary queue */ list_move_tail(&portq->portq_get_list, &portq->portq_list); glist = &portq->portq_get_list; /* use temporary event queue */ tnent = portq->portq_nent; /* get current number of events */ portq->portq_nent = 0; /* no events in the port event queue */ portq->portq_flags |= PORTQ_WAIT_EVENTS; /* detect incoming events */ mutex_exit(&portq->portq_mutex); /* event queue can be reused now */ if (model == DATAMODEL_NATIVE) { eventsz = sizeof (port_event_t); kevp = kmem_alloc(eventsz * nmax, KM_NOSLEEP); if (kevp == NULL) { if (nmax > pp->port_max_list) nmax = pp->port_max_list; kevp = kmem_alloc(eventsz * nmax, KM_SLEEP); } results = kevp; lev = NULL; /* start with first event in the queue */ for (nevents = 0; nevents < nmax; ) { pev = port_get_kevent(glist, lev); if (pev == NULL) /* no more events available */ break; if (pev->portkev_flags & PORT_KEV_FREE) { /* Just discard event */ list_remove(glist, pev); pev->portkev_flags &= ~(PORT_CLEANUP_DONE); if (PORT_FREE_EVENT(pev)) port_free_event_local(pev, 0); tnent--; continue; } /* move event data to copyout list */ if (port_copy_event(&kevp[nevents], pev, glist)) { /* * Event can not be delivered to the * current process. */ if (lev != NULL) list_insert_after(glist, lev, pev); else list_insert_head(glist, pev); lev = pev; /* last checked event */ } else { nevents++; /* # of events ready */ } } #ifdef _SYSCALL32_IMPL } else { port_event32_t *kevp32; eventsz = sizeof (port_event32_t); kevp32 = kmem_alloc(eventsz * nmax, KM_NOSLEEP); if (kevp32 == NULL) { if (nmax > pp->port_max_list) nmax = pp->port_max_list; kevp32 = kmem_alloc(eventsz * nmax, KM_SLEEP); } results = kevp32; lev = NULL; /* start with first event in the queue */ for (nevents = 0; nevents < nmax; ) { pev = port_get_kevent(glist, lev); if (pev == NULL) /* no more events available */ break; if (pev->portkev_flags & PORT_KEV_FREE) { /* Just discard event */ list_remove(glist, pev); pev->portkev_flags &= ~(PORT_CLEANUP_DONE); if (PORT_FREE_EVENT(pev)) port_free_event_local(pev, 0); tnent--; continue; } /* move event data to copyout list */ if (port_copy_event32(&kevp32[nevents], pev, glist)) { /* * Event can not be delivered to the * current process. */ if (lev != NULL) list_insert_after(glist, lev, pev); else list_insert_head(glist, pev); lev = pev; /* last checked event */ } else { nevents++; /* # of events ready */ } } #endif /* _SYSCALL32_IMPL */ } /* * Remember number of remaining events in the temporary event queue. */ portq->portq_tnent = tnent - nevents; /* * Work to do before return : * - push list of remaining events back to the top of the standard * port queue. * - if this is the last thread calling port_get(n) then wakeup the * thread waiting on close(2). * - check for a deferred cv_signal from port_send_event() and wakeup * the sleeping thread. */ mutex_enter(&portq->portq_mutex); port_unblock(portq); if (portq->portq_tnent) { /* * move remaining events in the temporary event queue back * to the port event queue */ port_push_eventq(portq); } portq->portq_getn--; /* update # of threads retrieving events */ if (--portq->portq_thrcnt == 0) { /* # of threads waiting ... */ /* Last thread => check close(2) conditions ... */ if (portq->portq_flags & PORTQ_CLOSE) { cv_signal(&portq->portq_closecv); mutex_exit(&portq->portq_mutex); kmem_free(results, eventsz * nmax); /* do not copyout events */ *nget = 0; return (EBADFD); } } else if (portq->portq_getn == 0) { /* * no other threads retrieving events ... * check wakeup conditions of sleeping threads */ if ((portq->portq_thread != NULL) && (portq->portq_nent >= portq->portq_nget)) cv_signal(&portq->portq_thread->portget_cv); } /* * Check PORTQ_POLLIN here because the current thread set temporarily * the number of events in the queue to zero. */ if (portq->portq_flags & PORTQ_POLLIN) { portq->portq_flags &= ~PORTQ_POLLIN; mutex_exit(&portq->portq_mutex); pollwakeup(&pp->port_pollhd, POLLIN); } else { mutex_exit(&portq->portq_mutex); } /* now copyout list of user event structures to user space */ if (nevents) { if (copyout(results, uevp, nevents * eventsz)) error = EFAULT; } kmem_free(results, eventsz * nmax); if (nevents == 0 && error == 0 && pgt->pgt_loop == 0 && blocking != 0) { /* no events retrieved: check loop conditions */ if (blocking == -1) { /* no timeout checked */ error = port_get_timeout(pgt->pgt_timeout, &pgt->pgt_rqtime, &rqtp, &blocking, flag); if (error) { *nget = nevents; return (error); } if (rqtp != NULL) { timespec_t now; gethrestime(&now); timespecadd(&pgt->pgt_rqtime, &now); } pgt->pgt_rqtp = rqtp; } else { /* timeout already checked -> remember values */ pgt->pgt_rqtp = rqtp; if (rqtp != NULL) { pgt->pgt_rqtime = *rqtp; } } if (blocking) /* timeout remaining */ pgt->pgt_loop = 1; } /* set number of user event structures completed */ *nget = nevents; return (error); } /* * 1. copy kernel event structure to user event structure. * 2. PORT_KEV_WIRED event structures will be reused by the "source" * 3. Remove PORT_KEV_DONEQ flag (event removed from the event queue) * 4. Other types of event structures can be delivered back to the port cache * (port_free_event_local()). * 5. The event source callback function is the last opportunity for the * event source to update events, to free local resources associated with * the event or to deny the delivery of the event. */ static int port_copy_event(port_event_t *puevp, port_kevent_t *pkevp, list_t *list) { int free_event = 0; int flags; int error; puevp->portev_source = pkevp->portkev_source; puevp->portev_object = pkevp->portkev_object; puevp->portev_user = pkevp->portkev_user; puevp->portev_events = pkevp->portkev_events; /* remove event from the queue */ list_remove(list, pkevp); /* * Events of type PORT_KEV_WIRED remain allocated by the * event source. */ flags = pkevp->portkev_flags; if (pkevp->portkev_flags & PORT_KEV_WIRED) pkevp->portkev_flags &= ~PORT_KEV_DONEQ; else free_event = 1; if (pkevp->portkev_callback) { error = (*pkevp->portkev_callback)(pkevp->portkev_arg, &puevp->portev_events, pkevp->portkev_pid, PORT_CALLBACK_DEFAULT, pkevp); if (error) { /* * Event can not be delivered. * Caller must reinsert the event into the queue. */ pkevp->portkev_flags = flags; return (error); } } if (free_event) port_free_event_local(pkevp, 0); return (0); } #ifdef _SYSCALL32_IMPL /* * 1. copy kernel event structure to user event structure. * 2. PORT_KEV_WIRED event structures will be reused by the "source" * 3. Remove PORT_KEV_DONEQ flag (event removed from the event queue) * 4. Other types of event structures can be delivered back to the port cache * (port_free_event_local()). * 5. The event source callback function is the last opportunity for the * event source to update events, to free local resources associated with * the event or to deny the delivery of the event. */ static int port_copy_event32(port_event32_t *puevp, port_kevent_t *pkevp, list_t *list) { int free_event = 0; int error; int flags; puevp->portev_source = pkevp->portkev_source; puevp->portev_object = (daddr32_t)pkevp->portkev_object; puevp->portev_user = (caddr32_t)(uintptr_t)pkevp->portkev_user; puevp->portev_events = pkevp->portkev_events; /* remove event from the queue */ list_remove(list, pkevp); /* * Events if type PORT_KEV_WIRED remain allocated by the * sub-system (source). */ flags = pkevp->portkev_flags; if (pkevp->portkev_flags & PORT_KEV_WIRED) pkevp->portkev_flags &= ~PORT_KEV_DONEQ; else free_event = 1; if (pkevp->portkev_callback != NULL) { error = (*pkevp->portkev_callback)(pkevp->portkev_arg, &puevp->portev_events, pkevp->portkev_pid, PORT_CALLBACK_DEFAULT, pkevp); if (error) { /* * Event can not be delivered. * Caller must reinsert the event into the queue. */ pkevp->portkev_flags = flags; return (error); } } if (free_event) port_free_event_local(pkevp, 0); return (0); } #endif /* _SYSCALL32_IMPL */ /* * copyout alert event. */ static int port_get_alert(port_alert_t *pa, port_event_t *uevp) { model_t model = get_udatamodel(); /* copyout alert event structures to user space */ if (model == DATAMODEL_NATIVE) { port_event_t uev; uev.portev_source = PORT_SOURCE_ALERT; uev.portev_object = pa->portal_object; uev.portev_events = pa->portal_events; uev.portev_user = pa->portal_user; if (copyout(&uev, uevp, sizeof (port_event_t))) return (EFAULT); #ifdef _SYSCALL32_IMPL } else { port_event32_t uev32; uev32.portev_source = PORT_SOURCE_ALERT; uev32.portev_object = (daddr32_t)pa->portal_object; uev32.portev_events = pa->portal_events; uev32.portev_user = (daddr32_t)(uintptr_t)pa->portal_user; if (copyout(&uev32, uevp, sizeof (port_event32_t))) return (EFAULT); #endif /* _SYSCALL32_IMPL */ } return (0); } /* * Check return conditions : * - pending port close(2) * - threads waiting for events */ static void port_check_return_cond(port_queue_t *portq) { ASSERT(MUTEX_HELD(&portq->portq_mutex)); portq->portq_thrcnt--; if (portq->portq_flags & PORTQ_CLOSE) { if (portq->portq_thrcnt == 0) cv_signal(&portq->portq_closecv); else cv_signal(&portq->portq_thread->portget_cv); } } /* * The port_get_kevent() function returns * - the event located at the head of the queue if 'last' pointer is NULL * - the next event after the event pointed by 'last' * The caller of this function is responsible for the integrity of the queue * in use: * - port_getn() is using a temporary queue protected with port_block(). * - port_close_events() is working on the global event queue and protects * the queue with portq->portq_mutex. */ port_kevent_t * port_get_kevent(list_t *list, port_kevent_t *last) { if (last == NULL) return (list_head(list)); else return (list_next(list, last)); } /* * The port_get_timeout() function gets the timeout data from user space * and converts that info into a corresponding internal representation. * The kerneldata flag means that the timeout data is already loaded. */ static int port_get_timeout(timespec_t *timeout, timespec_t *rqtime, timespec_t **rqtp, int *blocking, int kerneldata) { model_t model = get_udatamodel(); *rqtp = NULL; if (timeout == NULL) { *blocking = 1; return (0); } if (kerneldata) { *rqtime = *timeout; } else { if (model == DATAMODEL_NATIVE) { if (copyin(timeout, rqtime, sizeof (*rqtime))) return (EFAULT); #ifdef _SYSCALL32_IMPL } else { timespec32_t wait_time_32; if (copyin(timeout, &wait_time_32, sizeof (wait_time_32))) return (EFAULT); TIMESPEC32_TO_TIMESPEC(rqtime, &wait_time_32); #endif /* _SYSCALL32_IMPL */ } } if (rqtime->tv_sec == 0 && rqtime->tv_nsec == 0) { *blocking = 0; return (0); } if (rqtime->tv_sec < 0 || rqtime->tv_nsec < 0 || rqtime->tv_nsec >= NANOSEC) return (EINVAL); *rqtp = rqtime; *blocking = 1; return (0); } /* * port_queue_thread() * Threads requiring more events than available will be put in a wait queue. * There is a "thread wait queue" per port. * Threads requiring less events get a higher priority than others and they * will be awoken first. */ static portget_t * port_queue_thread(port_queue_t *portq, uint_t nget) { portget_t *pgetp; portget_t *ttp; portget_t *htp; pgetp = kmem_zalloc(sizeof (portget_t), KM_SLEEP); pgetp->portget_nget = nget; pgetp->portget_pid = curproc->p_pid; if (portq->portq_thread == NULL) { /* first waiting thread */ portq->portq_thread = pgetp; portq->portq_nget = nget; pgetp->portget_prev = pgetp; pgetp->portget_next = pgetp; return (pgetp); } /* * thread waiting for less events will be set on top of the queue. */ ttp = portq->portq_thread; htp = ttp; for (;;) { if (nget <= ttp->portget_nget) break; if (htp == ttp->portget_next) break; /* last event */ ttp = ttp->portget_next; } /* add thread to the queue */ pgetp->portget_next = ttp; pgetp->portget_prev = ttp->portget_prev; ttp->portget_prev->portget_next = pgetp; ttp->portget_prev = pgetp; if (portq->portq_thread == ttp) portq->portq_thread = pgetp; portq->portq_nget = portq->portq_thread->portget_nget; return (pgetp); } /* * Take thread out of the queue. */ static void port_dequeue_thread(port_queue_t *portq, portget_t *pgetp) { if (pgetp->portget_next == pgetp) { /* last (single) waiting thread */ portq->portq_thread = NULL; portq->portq_nget = 0; } else { pgetp->portget_prev->portget_next = pgetp->portget_next; pgetp->portget_next->portget_prev = pgetp->portget_prev; if (portq->portq_thread == pgetp) portq->portq_thread = pgetp->portget_next; portq->portq_nget = portq->portq_thread->portget_nget; } kmem_free(pgetp, sizeof (portget_t)); } /* * Set up event port kstats. */ static void port_kstat_init() { kstat_t *ksp; uint_t ndata; ndata = sizeof (port_kstat) / sizeof (kstat_named_t); ksp = kstat_create("portfs", 0, "Event Ports", "misc", KSTAT_TYPE_NAMED, ndata, KSTAT_FLAG_VIRTUAL); if (ksp) { ksp->ks_data = &port_kstat; kstat_install(ksp); } }