sys/kern/sys_aio.c

1.31     rmind /*	$NetBSD: sys_aio.c,v 1.31 2010/01/30 21:23:46 rmind Exp $	*/
 1.1     rmind
 1.1     rmind /*
1.31     rmind  * Copyright (c) 2007 Mindaugas Rasiukevicius <rmind at NetBSD org>
1.10     rmind  * All rights reserved.
 1.1     rmind  *
 1.1     rmind  * Redistribution and use in source and binary forms, with or without
 1.1     rmind  * modification, are permitted provided that the following conditions
 1.1     rmind  * are met:
 1.1     rmind  * 1. Redistributions of source code must retain the above copyright
 1.1     rmind  *    notice, this list of conditions and the following disclaimer.
 1.1     rmind  * 2. Redistributions in binary form must reproduce the above copyright
 1.1     rmind  *    notice, this list of conditions and the following disclaimer in the
 1.1     rmind  *    documentation and/or other materials provided with the distribution.
 1.1     rmind  *
1.19     rmind  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
1.19     rmind  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.19     rmind  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.19     rmind  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
1.19     rmind  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.19     rmind  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.19     rmind  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.19     rmind  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.19     rmind  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.19     rmind  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.19     rmind  * SUCH DAMAGE.
 1.1     rmind  */
 1.1     rmind
 1.1     rmind /*
1.19     rmind  * Implementation of POSIX asynchronous I/O.
1.19     rmind  * Defined in the Base Definitions volume of IEEE Std 1003.1-2001.
 1.1     rmind  */
 1.1     rmind
 1.1     rmind #include <sys/cdefs.h>
1.31     rmind __KERNEL_RCSID(0, "$NetBSD: sys_aio.c,v 1.31 2010/01/30 21:23:46 rmind Exp $");
 1.4     rmind
1.20        ad #ifdef _KERNEL_OPT
 1.4     rmind #include "opt_ddb.h"
1.20        ad #endif
 1.1     rmind
 1.1     rmind #include <sys/param.h>
 1.1     rmind #include <sys/condvar.h>
 1.1     rmind #include <sys/file.h>
 1.1     rmind #include <sys/filedesc.h>
 1.1     rmind #include <sys/kernel.h>
 1.1     rmind #include <sys/kmem.h>
 1.1     rmind #include <sys/lwp.h>
 1.1     rmind #include <sys/mutex.h>
 1.1     rmind #include <sys/pool.h>
 1.1     rmind #include <sys/proc.h>
 1.1     rmind #include <sys/queue.h>
 1.1     rmind #include <sys/signal.h>
 1.1     rmind #include <sys/signalvar.h>
1.20        ad #include <sys/syscall.h>
 1.1     rmind #include <sys/syscallargs.h>
1.20        ad #include <sys/syscallvar.h>
 1.1     rmind #include <sys/sysctl.h>
 1.1     rmind #include <sys/systm.h>
 1.1     rmind #include <sys/types.h>
 1.1     rmind #include <sys/vnode.h>
1.11        ad #include <sys/atomic.h>
1.20        ad #include <sys/module.h>
1.21     pooka #include <sys/buf.h>
 1.1     rmind
 1.1     rmind #include <uvm/uvm_extern.h>
 1.1     rmind
1.20        ad MODULE(MODULE_CLASS_MISC, aio, NULL);
1.20        ad
 1.1     rmind /*
 1.1     rmind  * System-wide limits and counter of AIO operations.
 1.1     rmind  */
1.31     rmind u_int			aio_listio_max = AIO_LISTIO_MAX;
1.31     rmind static u_int		aio_max = AIO_MAX;
1.31     rmind static u_int		aio_jobs_count;
1.31     rmind
1.31     rmind static struct pool	aio_job_pool;
1.31     rmind static struct pool	aio_lio_pool;
1.31     rmind static void *		aio_ehook;
1.31     rmind
1.31     rmind static void	aio_worker(void *);
1.31     rmind static void	aio_process(struct aio_job *);
1.31     rmind static void	aio_sendsig(struct proc *, struct sigevent *);
1.31     rmind static int	aio_enqueue_job(int, void *, struct lio_req *);
1.31     rmind static void	aio_exit(proc_t *, void *);
1.20        ad
1.20        ad static const struct syscall_package aio_syscalls[] = {
1.20        ad 	{ SYS_aio_cancel, 0, (sy_call_t *)sys_aio_cancel },
1.20        ad 	{ SYS_aio_error, 0, (sy_call_t *)sys_aio_error },
1.20        ad 	{ SYS_aio_fsync, 0, (sy_call_t *)sys_aio_fsync },
1.20        ad 	{ SYS_aio_read, 0, (sy_call_t *)sys_aio_read },
1.20        ad 	{ SYS_aio_return, 0, (sy_call_t *)sys_aio_return },
1.22  christos 	{ SYS___aio_suspend50, 0, (sy_call_t *)sys___aio_suspend50 },
1.20        ad 	{ SYS_aio_write, 0, (sy_call_t *)sys_aio_write },
1.20        ad 	{ SYS_lio_listio, 0, (sy_call_t *)sys_lio_listio },
1.20        ad 	{ 0, 0, NULL },
1.20        ad };
 1.1     rmind
 1.1     rmind /*
1.20        ad  * Tear down all AIO state.
 1.4     rmind  */
1.20        ad static int
1.20        ad aio_fini(bool interface)
1.20        ad {
1.20        ad 	int error;
1.20        ad 	proc_t *p;
1.20        ad
1.20        ad 	if (interface) {
1.20        ad 		/* Stop syscall activity. */
1.20        ad 		error = syscall_disestablish(NULL, aio_syscalls);
1.20        ad 		if (error != 0)
1.20        ad 			return error;
1.20        ad 		/* Abort if any processes are using AIO. */
1.20        ad 		mutex_enter(proc_lock);
1.20        ad 		PROCLIST_FOREACH(p, &allproc) {
1.20        ad 			if (p->p_aio != NULL)
1.20        ad 				break;
1.20        ad 		}
1.20        ad 		mutex_exit(proc_lock);
1.20        ad 		if (p != NULL) {
1.20        ad 			error = syscall_establish(NULL, aio_syscalls);
1.20        ad 			KASSERT(error == 0);
1.20        ad 			return EBUSY;
1.20        ad 		}
1.20        ad 	}
1.20        ad 	KASSERT(aio_jobs_count == 0);
1.20        ad 	exithook_disestablish(aio_ehook);
1.20        ad 	pool_destroy(&aio_job_pool);
1.20        ad 	pool_destroy(&aio_lio_pool);
1.20        ad 	return 0;
1.20        ad }
1.20        ad
1.20        ad /*
1.20        ad  * Initialize global AIO state.
1.20        ad  */
1.20        ad static int
1.20        ad aio_init(void)
 1.4     rmind {
1.20        ad 	int error;
 1.4     rmind
 1.4     rmind 	pool_init(&aio_job_pool, sizeof(struct aio_job), 0, 0, 0,
 1.4     rmind 	    "aio_jobs_pool", &pool_allocator_nointr, IPL_NONE);
 1.4     rmind 	pool_init(&aio_lio_pool, sizeof(struct lio_req), 0, 0, 0,
 1.4     rmind 	    "aio_lio_pool", &pool_allocator_nointr, IPL_NONE);
1.20        ad 	aio_ehook = exithook_establish(aio_exit, NULL);
1.20        ad 	error = syscall_establish(NULL, aio_syscalls);
1.20        ad 	if (error != 0)
1.20        ad 		aio_fini(false);
1.20        ad 	return error;
1.20        ad }
1.20        ad
1.20        ad /*
1.20        ad  * Module interface.
1.20        ad  */
1.20        ad static int
1.20        ad aio_modcmd(modcmd_t cmd, void *arg)
1.20        ad {
1.20        ad
1.20        ad 	switch (cmd) {
1.20        ad 	case MODULE_CMD_INIT:
1.20        ad 		return aio_init();
1.20        ad 	case MODULE_CMD_FINI:
1.20        ad 		return aio_fini(true);
1.20        ad 	default:
1.20        ad 		return ENOTTY;
1.20        ad 	}
 1.4     rmind }
 1.4     rmind
 1.4     rmind /*
 1.1     rmind  * Initialize Asynchronous I/O data structures for the process.
 1.1     rmind  */
1.20        ad static int
1.20        ad aio_procinit(struct proc *p)
 1.1     rmind {
 1.1     rmind 	struct aioproc *aio;
 1.1     rmind 	struct lwp *l;
 1.8        ad 	int error;
 1.1     rmind 	vaddr_t uaddr;
 1.1     rmind
 1.1     rmind 	/* Allocate and initialize AIO structure */
1.15        ad 	aio = kmem_zalloc(sizeof(struct aioproc), KM_SLEEP);
 1.1     rmind 	if (aio == NULL)
 1.1     rmind 		return EAGAIN;
 1.1     rmind
 1.4     rmind 	/* Initialize queue and their synchronization structures */
 1.1     rmind 	mutex_init(&aio->aio_mtx, MUTEX_DEFAULT, IPL_NONE);
 1.1     rmind 	cv_init(&aio->aio_worker_cv, "aiowork");
 1.1     rmind 	cv_init(&aio->done_cv, "aiodone");
 1.1     rmind 	TAILQ_INIT(&aio->jobs_queue);
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Create an AIO worker thread.
 1.1     rmind 	 * XXX: Currently, AIO thread is not protected against user's actions.
 1.1     rmind 	 */
1.29     rmind 	uaddr = uvm_uarea_alloc();
 1.1     rmind 	if (uaddr == 0) {
 1.5     rmind 		aio_exit(p, aio);
 1.1     rmind 		return EAGAIN;
 1.1     rmind 	}
1.29     rmind 	error = lwp_create(curlwp, p, uaddr, 0, NULL, 0, aio_worker,
 1.8        ad 	    NULL, &l, curlwp->l_class);
 1.8        ad 	if (error != 0) {
1.29     rmind 		uvm_uarea_free(uaddr);
 1.5     rmind 		aio_exit(p, aio);
 1.8        ad 		return error;
 1.1     rmind 	}
 1.1     rmind
 1.5     rmind 	/* Recheck if we are really first */
1.18        ad 	mutex_enter(p->p_lock);
 1.5     rmind 	if (p->p_aio) {
1.18        ad 		mutex_exit(p->p_lock);
 1.5     rmind 		aio_exit(p, aio);
 1.5     rmind 		lwp_exit(l);
 1.5     rmind 		return 0;
 1.5     rmind 	}
 1.5     rmind 	p->p_aio = aio;
 1.5     rmind
 1.1     rmind 	/* Complete the initialization of thread, and run it */
 1.1     rmind 	aio->aio_worker = l;
 1.1     rmind 	p->p_nrlwps++;
 1.1     rmind 	lwp_lock(l);
 1.1     rmind 	l->l_stat = LSRUN;
1.12     rmind 	l->l_priority = MAXPRI_USER;
 1.2      yamt 	sched_enqueue(l, false);
 1.1     rmind 	lwp_unlock(l);
1.18        ad 	mutex_exit(p->p_lock);
 1.1     rmind
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * Exit of Asynchronous I/O subsystem of process.
 1.1     rmind  */
1.20        ad static void
1.20        ad aio_exit(struct proc *p, void *cookie)
 1.1     rmind {
 1.1     rmind 	struct aio_job *a_job;
1.20        ad 	struct aioproc *aio;
 1.1     rmind
1.20        ad 	if (cookie != NULL)
1.20        ad 		aio = cookie;
1.20        ad 	else if ((aio = p->p_aio) == NULL)
 1.1     rmind 		return;
 1.1     rmind
 1.1     rmind 	/* Free AIO queue */
 1.1     rmind 	while (!TAILQ_EMPTY(&aio->jobs_queue)) {
 1.1     rmind 		a_job = TAILQ_FIRST(&aio->jobs_queue);
 1.1     rmind 		TAILQ_REMOVE(&aio->jobs_queue, a_job, list);
 1.4     rmind 		pool_put(&aio_job_pool, a_job);
1.11        ad 		atomic_dec_uint(&aio_jobs_count);
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	/* Destroy and free the entire AIO data structure */
 1.1     rmind 	cv_destroy(&aio->aio_worker_cv);
 1.1     rmind 	cv_destroy(&aio->done_cv);
 1.1     rmind 	mutex_destroy(&aio->aio_mtx);
 1.1     rmind 	kmem_free(aio, sizeof(struct aioproc));
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * AIO worker thread and processor.
 1.1     rmind  */
1.26      yamt static void
 1.1     rmind aio_worker(void *arg)
 1.1     rmind {
 1.1     rmind 	struct proc *p = curlwp->l_proc;
 1.1     rmind 	struct aioproc *aio = p->p_aio;
 1.1     rmind 	struct aio_job *a_job;
 1.1     rmind 	struct lio_req *lio;
 1.1     rmind 	sigset_t oss, nss;
 1.4     rmind 	int error, refcnt;
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Make an empty signal mask, so it
 1.1     rmind 	 * handles only SIGKILL and SIGSTOP.
 1.1     rmind 	 */
 1.1     rmind 	sigfillset(&nss);
1.18        ad 	mutex_enter(p->p_lock);
 1.1     rmind 	error = sigprocmask1(curlwp, SIG_SETMASK, &nss, &oss);
1.18        ad 	mutex_exit(p->p_lock);
 1.1     rmind 	KASSERT(error == 0);
 1.1     rmind
 1.1     rmind 	for (;;) {
 1.1     rmind 		/*
 1.1     rmind 		 * Loop for each job in the queue.  If there
 1.4     rmind 		 * are no jobs then sleep.
 1.1     rmind 		 */
 1.1     rmind 		mutex_enter(&aio->aio_mtx);
 1.1     rmind 		while ((a_job = TAILQ_FIRST(&aio->jobs_queue)) == NULL) {
 1.1     rmind 			if (cv_wait_sig(&aio->aio_worker_cv, &aio->aio_mtx)) {
 1.1     rmind 				/*
 1.4     rmind 				 * Thread was interrupted - check for
 1.4     rmind 				 * pending exit or suspend.
 1.1     rmind 				 */
 1.4     rmind 				mutex_exit(&aio->aio_mtx);
 1.4     rmind 				lwp_userret(curlwp);
 1.4     rmind 				mutex_enter(&aio->aio_mtx);
 1.1     rmind 			}
 1.1     rmind 		}
 1.1     rmind
 1.1     rmind 		/* Take the job from the queue */
 1.1     rmind 		aio->curjob = a_job;
 1.1     rmind 		TAILQ_REMOVE(&aio->jobs_queue, a_job, list);
 1.1     rmind
1.11        ad 		atomic_dec_uint(&aio_jobs_count);
 1.1     rmind 		aio->jobs_count--;
 1.1     rmind
 1.1     rmind 		mutex_exit(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 		/* Process an AIO operation */
 1.1     rmind 		aio_process(a_job);
 1.1     rmind
 1.1     rmind 		/* Copy data structure back to the user-space */
 1.1     rmind 		(void)copyout(&a_job->aiocbp, a_job->aiocb_uptr,
 1.1     rmind 		    sizeof(struct aiocb));
 1.1     rmind
 1.1     rmind 		mutex_enter(&aio->aio_mtx);
 1.1     rmind 		aio->curjob = NULL;
 1.4     rmind
 1.1     rmind 		/* Decrease a reference counter, if there is a LIO structure */
 1.1     rmind 		lio = a_job->lio;
 1.4     rmind 		refcnt = (lio != NULL ? --lio->refcnt : -1);
 1.4     rmind
 1.1     rmind 		/* Notify all suspenders */
 1.1     rmind 		cv_broadcast(&aio->done_cv);
 1.1     rmind 		mutex_exit(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 		/* Send a signal, if any */
 1.1     rmind 		aio_sendsig(p, &a_job->aiocbp.aio_sigevent);
 1.1     rmind
 1.1     rmind 		/* Destroy the LIO structure */
 1.4     rmind 		if (refcnt == 0) {
 1.1     rmind 			aio_sendsig(p, &lio->sig);
 1.4     rmind 			pool_put(&aio_lio_pool, lio);
 1.1     rmind 		}
 1.1     rmind
1.30   mbalmer 		/* Destroy the job */
 1.4     rmind 		pool_put(&aio_job_pool, a_job);
 1.1     rmind 	}
 1.1     rmind
 1.4     rmind 	/* NOTREACHED */
 1.1     rmind }
 1.1     rmind
 1.1     rmind static void
 1.1     rmind aio_process(struct aio_job *a_job)
 1.1     rmind {
 1.1     rmind 	struct proc *p = curlwp->l_proc;
 1.1     rmind 	struct aiocb *aiocbp = &a_job->aiocbp;
 1.1     rmind 	struct file *fp;
 1.1     rmind 	int fd = aiocbp->aio_fildes;
 1.1     rmind 	int error = 0;
 1.1     rmind
 1.1     rmind 	KASSERT(a_job->aio_op != 0);
 1.1     rmind
 1.4     rmind 	if ((a_job->aio_op & (AIO_READ | AIO_WRITE)) != 0) {
 1.1     rmind 		struct iovec aiov;
 1.1     rmind 		struct uio auio;
 1.1     rmind
 1.1     rmind 		if (aiocbp->aio_nbytes > SSIZE_MAX) {
 1.1     rmind 			error = EINVAL;
 1.1     rmind 			goto done;
 1.1     rmind 		}
 1.1     rmind
1.16        ad 		fp = fd_getfile(fd);
 1.1     rmind 		if (fp == NULL) {
 1.1     rmind 			error = EBADF;
 1.1     rmind 			goto done;
 1.1     rmind 		}
 1.1     rmind
 1.1     rmind 		aiov.iov_base = (void *)(uintptr_t)aiocbp->aio_buf;
 1.1     rmind 		aiov.iov_len = aiocbp->aio_nbytes;
 1.1     rmind 		auio.uio_iov = &aiov;
 1.1     rmind 		auio.uio_iovcnt = 1;
 1.1     rmind 		auio.uio_resid = aiocbp->aio_nbytes;
 1.1     rmind 		auio.uio_vmspace = p->p_vmspace;
 1.1     rmind
 1.1     rmind 		if (a_job->aio_op & AIO_READ) {
 1.1     rmind 			/*
 1.1     rmind 			 * Perform a Read operation
 1.1     rmind 			 */
 1.1     rmind 			KASSERT((a_job->aio_op & AIO_WRITE) == 0);
 1.1     rmind
 1.1     rmind 			if ((fp->f_flag & FREAD) == 0) {
1.16        ad 				fd_putfile(fd);
 1.1     rmind 				error = EBADF;
 1.1     rmind 				goto done;
 1.1     rmind 			}
 1.1     rmind 			auio.uio_rw = UIO_READ;
 1.1     rmind 			error = (*fp->f_ops->fo_read)(fp, &aiocbp->aio_offset,
 1.1     rmind 			    &auio, fp->f_cred, FOF_UPDATE_OFFSET);
 1.1     rmind 		} else {
 1.1     rmind 			/*
 1.1     rmind 			 * Perform a Write operation
 1.1     rmind 			 */
 1.1     rmind 			KASSERT(a_job->aio_op & AIO_WRITE);
 1.1     rmind
 1.1     rmind 			if ((fp->f_flag & FWRITE) == 0) {
1.16        ad 				fd_putfile(fd);
 1.1     rmind 				error = EBADF;
 1.1     rmind 				goto done;
 1.1     rmind 			}
 1.1     rmind 			auio.uio_rw = UIO_WRITE;
 1.1     rmind 			error = (*fp->f_ops->fo_write)(fp, &aiocbp->aio_offset,
 1.1     rmind 			    &auio, fp->f_cred, FOF_UPDATE_OFFSET);
 1.1     rmind 		}
1.16        ad 		fd_putfile(fd);
 1.1     rmind
 1.1     rmind 		/* Store the result value */
 1.1     rmind 		a_job->aiocbp.aio_nbytes -= auio.uio_resid;
 1.1     rmind 		a_job->aiocbp._retval = (error == 0) ?
 1.1     rmind 		    a_job->aiocbp.aio_nbytes : -1;
 1.1     rmind
 1.4     rmind 	} else if ((a_job->aio_op & (AIO_SYNC | AIO_DSYNC)) != 0) {
 1.1     rmind 		/*
 1.1     rmind 		 * Perform a file Sync operation
 1.1     rmind 		 */
 1.1     rmind 		struct vnode *vp;
 1.1     rmind
1.16        ad 		if ((error = fd_getvnode(fd, &fp)) != 0)
 1.1     rmind 			goto done;
 1.1     rmind
 1.1     rmind 		if ((fp->f_flag & FWRITE) == 0) {
1.16        ad 			fd_putfile(fd);
 1.1     rmind 			error = EBADF;
 1.1     rmind 			goto done;
 1.1     rmind 		}
 1.1     rmind
 1.1     rmind 		vp = (struct vnode *)fp->f_data;
 1.1     rmind 		vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
 1.1     rmind 		if (a_job->aio_op & AIO_DSYNC) {
 1.1     rmind 			error = VOP_FSYNC(vp, fp->f_cred,
 1.9     pooka 			    FSYNC_WAIT | FSYNC_DATAONLY, 0, 0);
 1.1     rmind 		} else if (a_job->aio_op & AIO_SYNC) {
 1.1     rmind 			error = VOP_FSYNC(vp, fp->f_cred,
 1.9     pooka 			    FSYNC_WAIT, 0, 0);
 1.1     rmind 		}
 1.1     rmind 		VOP_UNLOCK(vp, 0);
1.16        ad 		fd_putfile(fd);
 1.1     rmind
 1.1     rmind 		/* Store the result value */
 1.1     rmind 		a_job->aiocbp._retval = (error == 0) ? 0 : -1;
 1.1     rmind
 1.1     rmind 	} else
 1.1     rmind 		panic("aio_process: invalid operation code\n");
 1.1     rmind
 1.1     rmind done:
 1.1     rmind 	/* Job is done, set the error, if any */
 1.1     rmind 	a_job->aiocbp._errno = error;
 1.1     rmind 	a_job->aiocbp._state = JOB_DONE;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * Send AIO signal.
 1.1     rmind  */
 1.1     rmind static void
 1.1     rmind aio_sendsig(struct proc *p, struct sigevent *sig)
 1.1     rmind {
 1.1     rmind 	ksiginfo_t ksi;
 1.1     rmind
 1.1     rmind 	if (sig->sigev_signo == 0 || sig->sigev_notify == SIGEV_NONE)
 1.1     rmind 		return;
 1.1     rmind
 1.1     rmind 	KSI_INIT(&ksi);
 1.1     rmind 	ksi.ksi_signo = sig->sigev_signo;
 1.1     rmind 	ksi.ksi_code = SI_ASYNCIO;
 1.3  christos 	ksi.ksi_value = sig->sigev_value;
1.17        ad 	mutex_enter(proc_lock);
 1.1     rmind 	kpsignal(p, &ksi, NULL);
1.17        ad 	mutex_exit(proc_lock);
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * Enqueue the job.
 1.1     rmind  */
 1.1     rmind static int
 1.1     rmind aio_enqueue_job(int op, void *aiocb_uptr, struct lio_req *lio)
 1.1     rmind {
 1.1     rmind 	struct proc *p = curlwp->l_proc;
 1.1     rmind 	struct aioproc *aio;
 1.1     rmind 	struct aio_job *a_job;
 1.1     rmind 	struct aiocb aiocbp;
 1.1     rmind 	struct sigevent *sig;
 1.1     rmind 	int error;
 1.1     rmind
1.12     rmind 	/* Non-accurate check for the limit */
1.12     rmind 	if (aio_jobs_count + 1 > aio_max)
 1.1     rmind 		return EAGAIN;
 1.1     rmind
 1.1     rmind 	/* Get the data structure from user-space */
 1.1     rmind 	error = copyin(aiocb_uptr, &aiocbp, sizeof(struct aiocb));
 1.1     rmind 	if (error)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	/* Check if signal is set, and validate it */
 1.1     rmind 	sig = &aiocbp.aio_sigevent;
 1.1     rmind 	if (sig->sigev_signo < 0 || sig->sigev_signo >= NSIG ||
 1.1     rmind 	    sig->sigev_notify < SIGEV_NONE || sig->sigev_notify > SIGEV_SA)
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	/* Buffer and byte count */
 1.1     rmind 	if (((AIO_SYNC | AIO_DSYNC) & op) == 0)
 1.1     rmind 		if (aiocbp.aio_buf == NULL || aiocbp.aio_nbytes > SSIZE_MAX)
 1.1     rmind 			return EINVAL;
 1.1     rmind
 1.1     rmind 	/* Check the opcode, if LIO_NOP - simply ignore */
 1.1     rmind 	if (op == AIO_LIO) {
 1.1     rmind 		KASSERT(lio != NULL);
 1.1     rmind 		if (aiocbp.aio_lio_opcode == LIO_WRITE)
 1.1     rmind 			op = AIO_WRITE;
 1.1     rmind 		else if (aiocbp.aio_lio_opcode == LIO_READ)
 1.1     rmind 			op = AIO_READ;
 1.1     rmind 		else
 1.1     rmind 			return (aiocbp.aio_lio_opcode == LIO_NOP) ? 0 : EINVAL;
 1.1     rmind 	} else {
 1.1     rmind 		KASSERT(lio == NULL);
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Look for already existing job.  If found - the job is in-progress.
 1.1     rmind 	 * According to POSIX this is invalid, so return the error.
 1.1     rmind 	 */
 1.1     rmind 	aio = p->p_aio;
 1.1     rmind 	if (aio) {
 1.1     rmind 		mutex_enter(&aio->aio_mtx);
 1.1     rmind 		if (aio->curjob) {
 1.1     rmind 			a_job = aio->curjob;
 1.1     rmind 			if (a_job->aiocb_uptr == aiocb_uptr) {
 1.1     rmind 				mutex_exit(&aio->aio_mtx);
 1.1     rmind 				return EINVAL;
 1.1     rmind 			}
 1.1     rmind 		}
 1.1     rmind 		TAILQ_FOREACH(a_job, &aio->jobs_queue, list) {
 1.1     rmind 			if (a_job->aiocb_uptr != aiocb_uptr)
 1.1     rmind 				continue;
 1.1     rmind 			mutex_exit(&aio->aio_mtx);
 1.1     rmind 			return EINVAL;
 1.1     rmind 		}
 1.1     rmind 		mutex_exit(&aio->aio_mtx);
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Check if AIO structure is initialized, if not - initialize it.
 1.1     rmind 	 * In LIO case, we did that already.  We will recheck this with
1.20        ad 	 * the lock in aio_procinit().
 1.1     rmind 	 */
 1.1     rmind 	if (lio == NULL && p->p_aio == NULL)
1.20        ad 		if (aio_procinit(p))
 1.1     rmind 			return EAGAIN;
 1.1     rmind 	aio = p->p_aio;
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Set the state with errno, and copy data
 1.1     rmind 	 * structure back to the user-space.
 1.1     rmind 	 */
 1.1     rmind 	aiocbp._state = JOB_WIP;
 1.1     rmind 	aiocbp._errno = EINPROGRESS;
 1.1     rmind 	aiocbp._retval = -1;
 1.1     rmind 	error = copyout(&aiocbp, aiocb_uptr, sizeof(struct aiocb));
 1.1     rmind 	if (error)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	/* Allocate and initialize a new AIO job */
 1.4     rmind 	a_job = pool_get(&aio_job_pool, PR_WAITOK);
 1.1     rmind 	memset(a_job, 0, sizeof(struct aio_job));
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Set the data.
 1.1     rmind 	 * Store the user-space pointer for searching.  Since we
 1.1     rmind 	 * are storing only per proc pointers - it is safe.
 1.1     rmind 	 */
 1.1     rmind 	memcpy(&a_job->aiocbp, &aiocbp, sizeof(struct aiocb));
 1.1     rmind 	a_job->aiocb_uptr = aiocb_uptr;
 1.1     rmind 	a_job->aio_op |= op;
 1.1     rmind 	a_job->lio = lio;
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * Add the job to the queue, update the counters, and
 1.1     rmind 	 * notify the AIO worker thread to handle the job.
 1.1     rmind 	 */
 1.1     rmind 	mutex_enter(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 	/* Fail, if the limit was reached */
1.13     rmind 	if (atomic_inc_uint_nv(&aio_jobs_count) > aio_max ||
1.13     rmind 	    aio->jobs_count >= aio_listio_max) {
1.12     rmind 		atomic_dec_uint(&aio_jobs_count);
 1.1     rmind 		mutex_exit(&aio->aio_mtx);
 1.4     rmind 		pool_put(&aio_job_pool, a_job);
 1.1     rmind 		return EAGAIN;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	TAILQ_INSERT_TAIL(&aio->jobs_queue, a_job, list);
 1.1     rmind 	aio->jobs_count++;
 1.1     rmind 	if (lio)
 1.1     rmind 		lio->refcnt++;
 1.1     rmind 	cv_signal(&aio->aio_worker_cv);
 1.1     rmind
 1.1     rmind 	mutex_exit(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 	/*
 1.1     rmind 	 * One would handle the errors only with aio_error() function.
 1.1     rmind 	 * This way is appropriate according to POSIX.
 1.1     rmind 	 */
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * Syscall functions.
 1.1     rmind  */
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_cancel(struct lwp *l, const struct sys_aio_cancel_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(int) fildes;
 1.1     rmind 		syscallarg(struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind 	struct proc *p = l->l_proc;
 1.1     rmind 	struct aioproc *aio;
 1.1     rmind 	struct aio_job *a_job;
 1.1     rmind 	struct aiocb *aiocbp_ptr;
 1.1     rmind 	struct lio_req *lio;
 1.1     rmind 	struct filedesc	*fdp = p->p_fd;
 1.1     rmind 	unsigned int cn, errcnt, fildes;
1.24        ad 	fdtab_t *dt;
 1.1     rmind
 1.1     rmind 	TAILQ_HEAD(, aio_job) tmp_jobs_list;
 1.1     rmind
 1.1     rmind 	/* Check for invalid file descriptor */
 1.1     rmind 	fildes = (unsigned int)SCARG(uap, fildes);
1.24        ad 	dt = fdp->fd_dt;
1.24        ad 	if (fildes >= dt->dt_nfiles)
1.16        ad 		return EBADF;
1.24        ad 	if (dt->dt_ff[fildes] == NULL || dt->dt_ff[fildes]->ff_file == NULL)
 1.1     rmind 		return EBADF;
 1.1     rmind
 1.1     rmind 	/* Check if AIO structure is initialized */
 1.1     rmind 	if (p->p_aio == NULL) {
 1.1     rmind 		*retval = AIO_NOTCANCELED;
 1.1     rmind 		return 0;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	aio = p->p_aio;
 1.1     rmind 	aiocbp_ptr = (struct aiocb *)SCARG(uap, aiocbp);
 1.1     rmind
 1.1     rmind 	mutex_enter(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 	/* Cancel the jobs, and remove them from the queue */
 1.1     rmind 	cn = 0;
 1.1     rmind 	TAILQ_INIT(&tmp_jobs_list);
 1.1     rmind 	TAILQ_FOREACH(a_job, &aio->jobs_queue, list) {
 1.1     rmind 		if (aiocbp_ptr) {
 1.1     rmind 			if (aiocbp_ptr != a_job->aiocb_uptr)
 1.1     rmind 				continue;
 1.1     rmind 			if (fildes != a_job->aiocbp.aio_fildes) {
 1.1     rmind 				mutex_exit(&aio->aio_mtx);
 1.1     rmind 				return EBADF;
 1.1     rmind 			}
 1.1     rmind 		} else if (a_job->aiocbp.aio_fildes != fildes)
 1.1     rmind 			continue;
 1.1     rmind
 1.1     rmind 		TAILQ_REMOVE(&aio->jobs_queue, a_job, list);
 1.1     rmind 		TAILQ_INSERT_TAIL(&tmp_jobs_list, a_job, list);
 1.1     rmind
 1.1     rmind 		/* Decrease the counters */
1.11        ad 		atomic_dec_uint(&aio_jobs_count);
 1.1     rmind 		aio->jobs_count--;
 1.1     rmind 		lio = a_job->lio;
 1.4     rmind 		if (lio != NULL && --lio->refcnt != 0)
 1.4     rmind 			a_job->lio = NULL;
 1.1     rmind
 1.1     rmind 		cn++;
 1.1     rmind 		if (aiocbp_ptr)
 1.1     rmind 			break;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	/* There are canceled jobs */
 1.1     rmind 	if (cn)
 1.1     rmind 		*retval = AIO_CANCELED;
 1.1     rmind
 1.1     rmind 	/* We cannot cancel current job */
 1.1     rmind 	a_job = aio->curjob;
 1.1     rmind 	if (a_job && ((a_job->aiocbp.aio_fildes == fildes) ||
 1.1     rmind 	    (a_job->aiocb_uptr == aiocbp_ptr)))
 1.1     rmind 		*retval = AIO_NOTCANCELED;
 1.1     rmind
 1.1     rmind 	mutex_exit(&aio->aio_mtx);
 1.1     rmind
 1.1     rmind 	/* Free the jobs after the lock */
 1.1     rmind 	errcnt = 0;
 1.1     rmind 	while (!TAILQ_EMPTY(&tmp_jobs_list)) {
 1.1     rmind 		a_job = TAILQ_FIRST(&tmp_jobs_list);
 1.1     rmind 		TAILQ_REMOVE(&tmp_jobs_list, a_job, list);
 1.1     rmind 		/* Set the errno and copy structures back to the user-space */
 1.1     rmind 		a_job->aiocbp._errno = ECANCELED;
 1.1     rmind 		a_job->aiocbp._state = JOB_DONE;
 1.1     rmind 		if (copyout(&a_job->aiocbp, a_job->aiocb_uptr,
 1.1     rmind 		    sizeof(struct aiocb)))
 1.1     rmind 			errcnt++;
 1.1     rmind 		/* Send a signal if any */
 1.1     rmind 		aio_sendsig(p, &a_job->aiocbp.aio_sigevent);
 1.6     rmind 		if (a_job->lio) {
 1.6     rmind 			lio = a_job->lio;
 1.6     rmind 			aio_sendsig(p, &lio->sig);
 1.6     rmind 			pool_put(&aio_lio_pool, lio);
 1.6     rmind 		}
 1.4     rmind 		pool_put(&aio_job_pool, a_job);
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	if (errcnt)
 1.1     rmind 		return EFAULT;
 1.1     rmind
 1.1     rmind 	/* Set a correct return value */
 1.1     rmind 	if (*retval == 0)
 1.1     rmind 		*retval = AIO_ALLDONE;
 1.1     rmind
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_error(struct lwp *l, const struct sys_aio_error_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(const struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind 	struct proc *p = l->l_proc;
 1.1     rmind 	struct aioproc *aio = p->p_aio;
 1.1     rmind 	struct aiocb aiocbp;
 1.1     rmind 	int error;
 1.1     rmind
 1.1     rmind 	if (aio == NULL)
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	error = copyin(SCARG(uap, aiocbp), &aiocbp, sizeof(struct aiocb));
 1.1     rmind 	if (error)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	if (aiocbp._state == JOB_NONE)
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	*retval = aiocbp._errno;
 1.1     rmind
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_fsync(struct lwp *l, const struct sys_aio_fsync_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(int) op;
 1.1     rmind 		syscallarg(struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind 	int op = SCARG(uap, op);
 1.1     rmind
 1.1     rmind 	if ((op != O_DSYNC) && (op != O_SYNC))
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	op = O_DSYNC ? AIO_DSYNC : AIO_SYNC;
 1.1     rmind
 1.1     rmind 	return aio_enqueue_job(op, SCARG(uap, aiocbp), NULL);
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_read(struct lwp *l, const struct sys_aio_read_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind
 1.1     rmind 	return aio_enqueue_job(AIO_READ, SCARG(uap, aiocbp), NULL);
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_return(struct lwp *l, const struct sys_aio_return_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind 	struct proc *p = l->l_proc;
 1.1     rmind 	struct aioproc *aio = p->p_aio;
 1.1     rmind 	struct aiocb aiocbp;
 1.1     rmind 	int error;
 1.1     rmind
 1.1     rmind 	if (aio == NULL)
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	error = copyin(SCARG(uap, aiocbp), &aiocbp, sizeof(struct aiocb));
 1.1     rmind 	if (error)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	if (aiocbp._errno == EINPROGRESS || aiocbp._state != JOB_DONE)
 1.1     rmind 		return EINVAL;
 1.1     rmind
 1.1     rmind 	*retval = aiocbp._retval;
 1.1     rmind
 1.1     rmind 	/* Reset the internal variables */
 1.1     rmind 	aiocbp._errno = 0;
 1.1     rmind 	aiocbp._retval = -1;
 1.1     rmind 	aiocbp._state = JOB_NONE;
 1.1     rmind 	error = copyout(&aiocbp, SCARG(uap, aiocbp), sizeof(struct aiocb));
 1.1     rmind
 1.1     rmind 	return error;
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.22  christos sys___aio_suspend50(struct lwp *l, const struct sys___aio_suspend50_args *uap,
1.22  christos     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(const struct aiocb *const[]) list;
 1.1     rmind 		syscallarg(int) nent;
 1.1     rmind 		syscallarg(const struct timespec *) timeout;
1.14       dsl 	} */
1.22  christos 	struct aiocb **list;
 1.1     rmind 	struct timespec ts;
1.22  christos 	int error, nent;
 1.1     rmind
 1.1     rmind 	nent = SCARG(uap, nent);
 1.1     rmind 	if (nent <= 0 || nent > aio_listio_max)
 1.1     rmind 		return EAGAIN;
 1.1     rmind
 1.1     rmind 	if (SCARG(uap, timeout)) {
 1.1     rmind 		/* Convert timespec to ticks */
 1.1     rmind 		error = copyin(SCARG(uap, timeout), &ts,
 1.1     rmind 		    sizeof(struct timespec));
 1.1     rmind 		if (error)
 1.1     rmind 			return error;
1.22  christos 	}
1.31     rmind
1.28      yamt 	list = kmem_alloc(nent * sizeof(*list), KM_SLEEP);
1.28      yamt 	error = copyin(SCARG(uap, list), list, nent * sizeof(*list));
1.22  christos 	if (error)
1.22  christos 		goto out;
1.22  christos 	error = aio_suspend1(l, list, nent, SCARG(uap, timeout) ? &ts : NULL);
1.22  christos out:
1.28      yamt 	kmem_free(list, nent * sizeof(*list));
1.22  christos 	return error;
1.22  christos }
1.22  christos
1.22  christos int
1.22  christos aio_suspend1(struct lwp *l, struct aiocb **aiocbp_list, int nent,
1.22  christos     struct timespec *ts)
1.22  christos {
1.22  christos 	struct proc *p = l->l_proc;
1.22  christos 	struct aioproc *aio;
1.22  christos 	struct aio_job *a_job;
1.22  christos 	int i, error, timo;
1.22  christos
1.22  christos 	if (p->p_aio == NULL)
1.22  christos 		return EAGAIN;
1.22  christos 	aio = p->p_aio;
1.22  christos
1.22  christos 	if (ts) {
1.22  christos 		timo = mstohz((ts->tv_sec * 1000) + (ts->tv_nsec / 1000000));
1.22  christos 		if (timo == 0 && ts->tv_sec == 0 && ts->tv_nsec > 0)
 1.1     rmind 			timo = 1;
 1.1     rmind 		if (timo <= 0)
 1.1     rmind 			return EAGAIN;
 1.1     rmind 	} else
 1.1     rmind 		timo = 0;
 1.1     rmind
 1.1     rmind 	mutex_enter(&aio->aio_mtx);
 1.1     rmind 	for (;;) {
 1.1     rmind 		for (i = 0; i < nent; i++) {
 1.1     rmind
 1.1     rmind 			/* Skip NULL entries */
 1.1     rmind 			if (aiocbp_list[i] == NULL)
 1.1     rmind 				continue;
 1.1     rmind
 1.1     rmind 			/* Skip current job */
 1.1     rmind 			if (aio->curjob) {
 1.1     rmind 				a_job = aio->curjob;
 1.1     rmind 				if (a_job->aiocb_uptr == aiocbp_list[i])
 1.1     rmind 					continue;
 1.1     rmind 			}
 1.1     rmind
 1.1     rmind 			/* Look for a job in the queue */
 1.1     rmind 			TAILQ_FOREACH(a_job, &aio->jobs_queue, list)
 1.1     rmind 				if (a_job->aiocb_uptr == aiocbp_list[i])
 1.1     rmind 					break;
 1.1     rmind
 1.1     rmind 			if (a_job == NULL) {
 1.1     rmind 				struct aiocb aiocbp;
 1.1     rmind
 1.1     rmind 				mutex_exit(&aio->aio_mtx);
 1.1     rmind
1.31     rmind 				/* Check if the job is done. */
 1.1     rmind 				error = copyin(aiocbp_list[i], &aiocbp,
 1.1     rmind 				    sizeof(struct aiocb));
 1.1     rmind 				if (error == 0 && aiocbp._state != JOB_DONE) {
 1.1     rmind 					mutex_enter(&aio->aio_mtx);
 1.1     rmind 					continue;
 1.1     rmind 				}
 1.1     rmind 				return error;
 1.1     rmind 			}
 1.1     rmind 		}
 1.1     rmind
 1.1     rmind 		/* Wait for a signal or when timeout occurs */
 1.1     rmind 		error = cv_timedwait_sig(&aio->done_cv, &aio->aio_mtx, timo);
 1.1     rmind 		if (error) {
 1.1     rmind 			if (error == EWOULDBLOCK)
 1.1     rmind 				error = EAGAIN;
 1.1     rmind 			break;
 1.1     rmind 		}
 1.1     rmind 	}
 1.1     rmind 	mutex_exit(&aio->aio_mtx);
 1.1     rmind 	return error;
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_aio_write(struct lwp *l, const struct sys_aio_write_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(struct aiocb *) aiocbp;
1.14       dsl 	} */
 1.1     rmind
 1.1     rmind 	return aio_enqueue_job(AIO_WRITE, SCARG(uap, aiocbp), NULL);
 1.1     rmind }
 1.1     rmind
 1.1     rmind int
1.27      yamt sys_lio_listio(struct lwp *l, const struct sys_lio_listio_args *uap,
1.27      yamt     register_t *retval)
 1.1     rmind {
1.14       dsl 	/* {
 1.1     rmind 		syscallarg(int) mode;
 1.1     rmind 		syscallarg(struct aiocb *const[]) list;
 1.1     rmind 		syscallarg(int) nent;
 1.1     rmind 		syscallarg(struct sigevent *) sig;
1.14       dsl 	} */
 1.1     rmind 	struct proc *p = l->l_proc;
 1.1     rmind 	struct aioproc *aio;
 1.1     rmind 	struct aiocb **aiocbp_list;
 1.1     rmind 	struct lio_req *lio;
 1.1     rmind 	int i, error, errcnt, mode, nent;
 1.1     rmind
 1.1     rmind 	mode = SCARG(uap, mode);
 1.1     rmind 	nent = SCARG(uap, nent);
 1.1     rmind
1.12     rmind 	/* Non-accurate checks for the limit and invalid values */
 1.1     rmind 	if (nent < 1 || nent > aio_listio_max)
 1.1     rmind 		return EINVAL;
1.12     rmind 	if (aio_jobs_count + nent > aio_max)
 1.1     rmind 		return EAGAIN;
 1.1     rmind
 1.1     rmind 	/* Check if AIO structure is initialized, if not - initialize it */
 1.1     rmind 	if (p->p_aio == NULL)
1.20        ad 		if (aio_procinit(p))
 1.1     rmind 			return EAGAIN;
 1.1     rmind 	aio = p->p_aio;
 1.1     rmind
 1.1     rmind 	/* Create a LIO structure */
 1.4     rmind 	lio = pool_get(&aio_lio_pool, PR_WAITOK);
 1.4     rmind 	lio->refcnt = 1;
 1.4     rmind 	error = 0;
 1.4     rmind
 1.4     rmind 	switch (mode) {
 1.4     rmind 	case LIO_WAIT:
 1.1     rmind 		memset(&lio->sig, 0, sizeof(struct sigevent));
 1.4     rmind 		break;
 1.4     rmind 	case LIO_NOWAIT:
 1.4     rmind 		/* Check for signal, validate it */
 1.4     rmind 		if (SCARG(uap, sig)) {
 1.4     rmind 			struct sigevent *sig = &lio->sig;
 1.4     rmind
 1.4     rmind 			error = copyin(SCARG(uap, sig), &lio->sig,
 1.4     rmind 			    sizeof(struct sigevent));
 1.4     rmind 			if (error == 0 &&
 1.4     rmind 			    (sig->sigev_signo < 0 ||
 1.4     rmind 			    sig->sigev_signo >= NSIG ||
 1.4     rmind 			    sig->sigev_notify < SIGEV_NONE ||
 1.4     rmind 			    sig->sigev_notify > SIGEV_SA))
 1.4     rmind 				error = EINVAL;
 1.4     rmind 		} else
 1.4     rmind 			memset(&lio->sig, 0, sizeof(struct sigevent));
 1.4     rmind 		break;
 1.4     rmind 	default:
 1.4     rmind 		error = EINVAL;
 1.4     rmind 		break;
 1.4     rmind 	}
 1.4     rmind
 1.4     rmind 	if (error != 0) {
 1.4     rmind 		pool_put(&aio_lio_pool, lio);
 1.4     rmind 		return error;
 1.4     rmind 	}
 1.1     rmind
 1.1     rmind 	/* Get the list from user-space */
1.28      yamt 	aiocbp_list = kmem_alloc(nent * sizeof(*aiocbp_list), KM_SLEEP);
 1.1     rmind 	error = copyin(SCARG(uap, list), aiocbp_list,
1.28      yamt 	    nent * sizeof(*aiocbp_list));
 1.4     rmind 	if (error) {
 1.4     rmind 		mutex_enter(&aio->aio_mtx);
 1.1     rmind 		goto err;
 1.4     rmind 	}
 1.1     rmind
 1.1     rmind 	/* Enqueue all jobs */
 1.1     rmind 	errcnt = 0;
 1.1     rmind 	for (i = 0; i < nent; i++) {
 1.1     rmind 		error = aio_enqueue_job(AIO_LIO, aiocbp_list[i], lio);
 1.1     rmind 		/*
 1.1     rmind 		 * According to POSIX, in such error case it may
 1.1     rmind 		 * fail with other I/O operations initiated.
 1.1     rmind 		 */
 1.1     rmind 		if (error)
 1.1     rmind 			errcnt++;
 1.1     rmind 	}
 1.1     rmind
 1.4     rmind 	mutex_enter(&aio->aio_mtx);
 1.4     rmind
 1.1     rmind 	/* Return an error, if any */
 1.1     rmind 	if (errcnt) {
 1.1     rmind 		error = EIO;
 1.1     rmind 		goto err;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	if (mode == LIO_WAIT) {
 1.1     rmind 		/*
 1.1     rmind 		 * Wait for AIO completion.  In such case,
 1.1     rmind 		 * the LIO structure will be freed here.
 1.1     rmind 		 */
 1.4     rmind 		while (lio->refcnt > 1 && error == 0)
 1.1     rmind 			error = cv_wait_sig(&aio->done_cv, &aio->aio_mtx);
 1.1     rmind 		if (error)
 1.1     rmind 			error = EINTR;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind err:
 1.4     rmind 	if (--lio->refcnt != 0)
 1.4     rmind 		lio = NULL;
 1.4     rmind 	mutex_exit(&aio->aio_mtx);
 1.4     rmind 	if (lio != NULL) {
 1.4     rmind 		aio_sendsig(p, &lio->sig);
 1.4     rmind 		pool_put(&aio_lio_pool, lio);
 1.4     rmind 	}
1.28      yamt 	kmem_free(aiocbp_list, nent * sizeof(*aiocbp_list));
 1.1     rmind 	return error;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * SysCtl
 1.1     rmind  */
 1.1     rmind
 1.1     rmind static int
 1.1     rmind sysctl_aio_listio_max(SYSCTLFN_ARGS)
 1.1     rmind {
 1.1     rmind 	struct sysctlnode node;
 1.1     rmind 	int error, newsize;
 1.1     rmind
 1.1     rmind 	node = *rnode;
 1.1     rmind 	node.sysctl_data = &newsize;
 1.1     rmind
 1.1     rmind 	newsize = aio_listio_max;
 1.1     rmind 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
 1.1     rmind 	if (error || newp == NULL)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	if (newsize < 1 || newsize > aio_max)
 1.1     rmind 		return EINVAL;
 1.1     rmind 	aio_listio_max = newsize;
 1.1     rmind
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind static int
 1.1     rmind sysctl_aio_max(SYSCTLFN_ARGS)
 1.1     rmind {
 1.1     rmind 	struct sysctlnode node;
 1.1     rmind 	int error, newsize;
 1.1     rmind
 1.1     rmind 	node = *rnode;
 1.1     rmind 	node.sysctl_data = &newsize;
 1.1     rmind
 1.1     rmind 	newsize = aio_max;
 1.1     rmind 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
 1.1     rmind 	if (error || newp == NULL)
 1.1     rmind 		return error;
 1.1     rmind
 1.1     rmind 	if (newsize < 1 || newsize < aio_listio_max)
 1.1     rmind 		return EINVAL;
 1.1     rmind 	aio_max = newsize;
 1.1     rmind
 1.1     rmind 	return 0;
 1.1     rmind }
 1.1     rmind
 1.1     rmind SYSCTL_SETUP(sysctl_aio_setup, "sysctl aio setup")
 1.1     rmind {
 1.1     rmind
 1.1     rmind 	sysctl_createv(clog, 0, NULL, NULL,
 1.1     rmind 		CTLFLAG_PERMANENT,
 1.1     rmind 		CTLTYPE_NODE, "kern", NULL,
 1.1     rmind 		NULL, 0, NULL, 0,
 1.1     rmind 		CTL_KERN, CTL_EOL);
 1.1     rmind 	sysctl_createv(clog, 0, NULL, NULL,
 1.1     rmind 		CTLFLAG_PERMANENT | CTLFLAG_IMMEDIATE,
 1.1     rmind 		CTLTYPE_INT, "posix_aio",
 1.1     rmind 		SYSCTL_DESCR("Version of IEEE Std 1003.1 and its "
 1.1     rmind 			     "Asynchronous I/O option to which the "
 1.1     rmind 			     "system attempts to conform"),
 1.1     rmind 		NULL, _POSIX_ASYNCHRONOUS_IO, NULL, 0,
 1.1     rmind 		CTL_KERN, CTL_CREATE, CTL_EOL);
 1.1     rmind 	sysctl_createv(clog, 0, NULL, NULL,
 1.1     rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
 1.1     rmind 		CTLTYPE_INT, "aio_listio_max",
 1.1     rmind 		SYSCTL_DESCR("Maximum number of asynchronous I/O "
 1.1     rmind 			     "operations in a single list I/O call"),
 1.1     rmind 		sysctl_aio_listio_max, 0, &aio_listio_max, 0,
 1.1     rmind 		CTL_KERN, CTL_CREATE, CTL_EOL);
 1.1     rmind 	sysctl_createv(clog, 0, NULL, NULL,
 1.1     rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
 1.1     rmind 		CTLTYPE_INT, "aio_max",
 1.1     rmind 		SYSCTL_DESCR("Maximum number of asynchronous I/O "
 1.1     rmind 			     "operations"),
 1.1     rmind 		sysctl_aio_max, 0, &aio_max, 0,
 1.1     rmind 		CTL_KERN, CTL_CREATE, CTL_EOL);
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * Debugging
 1.1     rmind  */
 1.1     rmind #if defined(DDB)
 1.1     rmind void
 1.1     rmind aio_print_jobs(void (*pr)(const char *, ...))
 1.1     rmind {
 1.1     rmind 	struct proc *p = (curlwp == NULL ? NULL : curlwp->l_proc);
 1.1     rmind 	struct aioproc *aio;
 1.1     rmind 	struct aio_job *a_job;
 1.1     rmind 	struct aiocb *aiocbp;
 1.1     rmind
 1.1     rmind 	if (p == NULL) {
 1.1     rmind 		(*pr)("AIO: We are not in the processes right now.\n");
 1.1     rmind 		return;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	aio = p->p_aio;
 1.1     rmind 	if (aio == NULL) {
 1.1     rmind 		(*pr)("AIO data is not initialized (PID = %d).\n", p->p_pid);
 1.1     rmind 		return;
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	(*pr)("AIO: PID = %d\n", p->p_pid);
 1.1     rmind 	(*pr)("AIO: Global count of the jobs = %u\n", aio_jobs_count);
 1.1     rmind 	(*pr)("AIO: Count of the jobs = %u\n", aio->jobs_count);
 1.1     rmind
 1.1     rmind 	if (aio->curjob) {
 1.1     rmind 		a_job = aio->curjob;
 1.1     rmind 		(*pr)("\nAIO current job:\n");
 1.1     rmind 		(*pr)(" opcode = %d, errno = %d, state = %d, aiocb_ptr = %p\n",
 1.1     rmind 		    a_job->aio_op, a_job->aiocbp._errno,
 1.1     rmind 		    a_job->aiocbp._state, a_job->aiocb_uptr);
 1.1     rmind 		aiocbp = &a_job->aiocbp;
 1.1     rmind 		(*pr)("   fd = %d, offset = %u, buf = %p, nbytes = %u\n",
 1.1     rmind 		    aiocbp->aio_fildes, aiocbp->aio_offset,
 1.1     rmind 		    aiocbp->aio_buf, aiocbp->aio_nbytes);
 1.1     rmind 	}
 1.1     rmind
 1.1     rmind 	(*pr)("\nAIO queue:\n");
 1.1     rmind 	TAILQ_FOREACH(a_job, &aio->jobs_queue, list) {
 1.1     rmind 		(*pr)(" opcode = %d, errno = %d, state = %d, aiocb_ptr = %p\n",
 1.1     rmind 		    a_job->aio_op, a_job->aiocbp._errno,
 1.1     rmind 		    a_job->aiocbp._state, a_job->aiocb_uptr);
 1.1     rmind 		aiocbp = &a_job->aiocbp;
 1.1     rmind 		(*pr)("   fd = %d, offset = %u, buf = %p, nbytes = %u\n",
 1.1     rmind 		    aiocbp->aio_fildes, aiocbp->aio_offset,
 1.1     rmind 		    aiocbp->aio_buf, aiocbp->aio_nbytes);
 1.1     rmind 	}
 1.1     rmind }
 1.1     rmind #endif /* defined(DDB) */