/* * 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 (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * UNIX Device Driver Interface functions * * This file contains functions that are to be added to the kernel * to put the interface presented to drivers in conformance with * the DDI standard. Of the functions added to the kernel, 17 are * function equivalents of existing macros in sysmacros.h, * stream.h, and param.h * * 17 additional functions -- drv_getparm(), drv_setparm(), * getrbuf(), freerbuf(), * getemajor(), geteminor(), etoimajor(), itoemajor(), drv_usectohz(), * drv_hztousec(), drv_usecwait(), drv_priv(), and kvtoppid() -- * are specified by DDI to exist in the kernel and are implemented here. * * Note that putnext() and put() are not in this file. The C version of * these routines are in uts/common/os/putnext.c and assembly versions * might exist for some architectures. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * return internal major number corresponding to device * number (new format) argument */ major_t getmajor(dev_t dev) { #ifdef _LP64 return ((major_t)((dev >> NBITSMINOR64) & MAXMAJ64)); #else return ((major_t)((dev >> NBITSMINOR) & MAXMAJ)); #endif } /* * return external major number corresponding to device * number (new format) argument */ major_t getemajor(dev_t dev) { #ifdef _LP64 return ((major_t)((dev >> NBITSMINOR64) & MAXMAJ64)); #else return ((major_t)((dev >> NBITSMINOR) & MAXMAJ)); #endif } /* * return internal minor number corresponding to device * number (new format) argument */ minor_t getminor(dev_t dev) { #ifdef _LP64 return ((minor_t)(dev & MAXMIN64)); #else return ((minor_t)(dev & MAXMIN)); #endif } /* * return external minor number corresponding to device * number (new format) argument */ minor_t geteminor(dev_t dev) { #ifdef _LP64 return ((minor_t)(dev & MAXMIN64)); #else return ((minor_t)(dev & MAXMIN)); #endif } /* * return internal major number corresponding to external * major number. */ int etoimajor(major_t emajnum) { #ifdef _LP64 if (emajnum >= devcnt) return (-1); /* invalid external major */ #else if (emajnum > MAXMAJ || emajnum >= devcnt) return (-1); /* invalid external major */ #endif return ((int)emajnum); } /* * return external major number corresponding to internal * major number argument or -1 if no external major number * can be found after lastemaj that maps to the internal * major number. Pass a lastemaj val of -1 to start * the search initially. (Typical use of this function is * of the form: * * lastemaj = -1; * while ((lastemaj = itoemajor(imag, lastemaj)) != -1) * { process major number } */ int itoemajor(major_t imajnum, int lastemaj) { if (imajnum >= devcnt) return (-1); /* * if lastemaj == -1 then start from beginning of * the (imaginary) MAJOR table */ if (lastemaj < -1) return (-1); /* * given that there's a 1-1 mapping of internal to external * major numbers, searching is somewhat pointless ... let's * just go there directly. */ if (++lastemaj < devcnt && imajnum < devcnt) return (imajnum); return (-1); } /* * encode external major and minor number arguments into a * new format device number */ dev_t makedevice(major_t maj, minor_t minor) { #ifdef _LP64 return (((dev_t)maj << NBITSMINOR64) | (minor & MAXMIN64)); #else return (((dev_t)maj << NBITSMINOR) | (minor & MAXMIN)); #endif } /* * cmpdev - compress new device format to old device format */ o_dev_t cmpdev(dev_t dev) { major_t major_d; minor_t minor_d; #ifdef _LP64 major_d = dev >> NBITSMINOR64; minor_d = dev & MAXMIN64; #else major_d = dev >> NBITSMINOR; minor_d = dev & MAXMIN; #endif if (major_d > OMAXMAJ || minor_d > OMAXMIN) return ((o_dev_t)NODEV); return ((o_dev_t)((major_d << ONBITSMINOR) | minor_d)); } dev_t expdev(dev_t dev) { major_t major_d; minor_t minor_d; major_d = ((dev >> ONBITSMINOR) & OMAXMAJ); minor_d = (dev & OMAXMIN); #ifdef _LP64 return ((((dev_t)major_d << NBITSMINOR64) | minor_d)); #else return ((((dev_t)major_d << NBITSMINOR) | minor_d)); #endif } /* * return true (1) if the message type input is a data * message type, 0 otherwise */ #undef datamsg int datamsg(unsigned char db_type) { return (db_type == M_DATA || db_type == M_PROTO || db_type == M_PCPROTO || db_type == M_DELAY); } /* * return a pointer to the other queue in the queue pair of qp */ queue_t * OTHERQ(queue_t *q) { return (_OTHERQ(q)); } /* * return a pointer to the read queue in the queue pair of qp. */ queue_t * RD(queue_t *q) { return (_RD(q)); } /* * return a pointer to the write queue in the queue pair of qp. */ int SAMESTR(queue_t *q) { return (_SAMESTR(q)); } /* * return a pointer to the write queue in the queue pair of qp. */ queue_t * WR(queue_t *q) { return (_WR(q)); } /* * store value of kernel parameter associated with parm */ int drv_getparm(unsigned int parm, void *valuep) { proc_t *p = curproc; time_t now; switch (parm) { case UPROCP: *(proc_t **)valuep = p; break; case PPGRP: mutex_enter(&p->p_lock); *(pid_t *)valuep = p->p_pgrp; mutex_exit(&p->p_lock); break; case LBOLT: *(clock_t *)valuep = ddi_get_lbolt(); break; case TIME: if ((now = gethrestime_sec()) == 0) { timestruc_t ts; mutex_enter(&tod_lock); ts = tod_get(); mutex_exit(&tod_lock); *(time_t *)valuep = ts.tv_sec; } else { *(time_t *)valuep = now; } break; case PPID: *(pid_t *)valuep = p->p_pid; break; case PSID: mutex_enter(&p->p_splock); *(pid_t *)valuep = p->p_sessp->s_sid; mutex_exit(&p->p_splock); break; case UCRED: *(cred_t **)valuep = CRED(); break; default: return (-1); } return (0); } /* * set value of kernel parameter associated with parm */ int drv_setparm(unsigned int parm, unsigned long value) { switch (parm) { case SYSRINT: CPU_STATS_ADDQ(CPU, sys, rcvint, value); break; case SYSXINT: CPU_STATS_ADDQ(CPU, sys, xmtint, value); break; case SYSMINT: CPU_STATS_ADDQ(CPU, sys, mdmint, value); break; case SYSRAWC: CPU_STATS_ADDQ(CPU, sys, rawch, value); break; case SYSCANC: CPU_STATS_ADDQ(CPU, sys, canch, value); break; case SYSOUTC: CPU_STATS_ADDQ(CPU, sys, outch, value); break; default: return (-1); } return (0); } /* * allocate space for buffer header and return pointer to it. * preferred means of obtaining space for a local buf header. * returns pointer to buf upon success, NULL for failure */ struct buf * getrbuf(int sleep) { struct buf *bp; bp = kmem_alloc(sizeof (struct buf), sleep); if (bp == NULL) return (NULL); bioinit(bp); return (bp); } /* * free up space allocated by getrbuf() */ void freerbuf(struct buf *bp) { biofini(bp); kmem_free(bp, sizeof (struct buf)); } /* * convert byte count input to logical page units * (byte counts that are not a page-size multiple * are rounded down) */ pgcnt_t btop(size_t numbytes) { return (numbytes >> PAGESHIFT); } /* * convert byte count input to logical page units * (byte counts that are not a page-size multiple * are rounded up) */ pgcnt_t btopr(size_t numbytes) { return ((numbytes + PAGEOFFSET) >> PAGESHIFT); } /* * convert size in pages to bytes. */ size_t ptob(pgcnt_t numpages) { return (numpages << PAGESHIFT); } #define MAXCLOCK_T LONG_MAX /* * Convert from system time units (hz) to microseconds. * * If ticks <= 0, return 0. * If converting ticks to usecs would overflow, return MAXCLOCK_T. * Otherwise, convert ticks to microseconds. */ clock_t drv_hztousec(clock_t ticks) { if (ticks <= 0) return (0); if (ticks > MAXCLOCK_T / usec_per_tick) return (MAXCLOCK_T); return (TICK_TO_USEC(ticks)); } /* * Convert from microseconds to system time units (hz), rounded up. * * If ticks <= 0, return 0. * Otherwise, convert microseconds to ticks, rounding up. */ clock_t drv_usectohz(clock_t microsecs) { if (microsecs <= 0) return (0); return (USEC_TO_TICK_ROUNDUP(microsecs)); } #ifdef sun /* * drv_usecwait implemented in each architecture's machine * specific code somewhere. For sparc, it is the alternate entry * to usec_delay (eventually usec_delay goes away). See * sparc/os/ml/sparc_subr.s */ #endif /* * bcanputnext, canputnext assume called from timeout, bufcall, * or esballoc free routines. since these are driven by * clock interrupts, instead of system calls the appropriate plumbing * locks have not been acquired. */ int bcanputnext(queue_t *q, unsigned char band) { int ret; claimstr(q); ret = bcanput(q->q_next, band); releasestr(q); return (ret); } int canputnext(queue_t *q) { queue_t *qofsq = q; struct stdata *stp = STREAM(q); kmutex_t *sdlock; TRACE_1(TR_FAC_STREAMS_FR, TR_CANPUTNEXT_IN, "canputnext?:%p\n", q); if (stp->sd_ciputctrl != NULL) { int ix = CPU->cpu_seqid & stp->sd_nciputctrl; sdlock = &stp->sd_ciputctrl[ix].ciputctrl_lock; mutex_enter(sdlock); } else mutex_enter(sdlock = &stp->sd_reflock); /* get next module forward with a service queue */ q = q->q_next->q_nfsrv; ASSERT(q != NULL); /* this is for loopback transports, they should not do a canputnext */ ASSERT(STRMATED(q->q_stream) || STREAM(q) == STREAM(qofsq)); if (!(q->q_flag & QFULL)) { mutex_exit(sdlock); TRACE_2(TR_FAC_STREAMS_FR, TR_CANPUTNEXT_OUT, "canputnext:%p %d", q, 1); return (1); } if (sdlock != &stp->sd_reflock) { mutex_exit(sdlock); mutex_enter(&stp->sd_reflock); } /* the above is the most frequently used path */ stp->sd_refcnt++; ASSERT(stp->sd_refcnt != 0); /* Wraparound */ mutex_exit(&stp->sd_reflock); mutex_enter(QLOCK(q)); if (q->q_flag & QFULL) { q->q_flag |= QWANTW; mutex_exit(QLOCK(q)); TRACE_2(TR_FAC_STREAMS_FR, TR_CANPUTNEXT_OUT, "canputnext:%p %d", q, 0); releasestr(qofsq); return (0); } mutex_exit(QLOCK(q)); TRACE_2(TR_FAC_STREAMS_FR, TR_CANPUTNEXT_OUT, "canputnext:%p %d", q, 1); releasestr(qofsq); return (1); } /* * Open has progressed to the point where it is safe to send/receive messages. * * "qprocson enables the put and service routines of the driver * or module... Prior to the call to qprocson, the put and service * routines of a newly pushed module or newly opened driver are * disabled. For the module, messages flow around it as if it * were not present in the stream... qprocson must be called by * the first open of a module or driver after allocation and * initialization of any resource on which the put and service * routines depend." * * Note that before calling qprocson a module/driver could itself cause its * put or service procedures to be run by using put() or qenable(). */ void qprocson(queue_t *q) { ASSERT(q->q_flag & QREADR); /* * Do not call insertq() if it is a re-open. But if _QINSERTING * is set, q_next will not be NULL and we need to call insertq(). */ if ((q->q_next == NULL && WR(q)->q_next == NULL) || (q->q_flag & _QINSERTING)) insertq(STREAM(q), q); } /* * Close has reached a point where it can no longer allow put/service * into the queue. * * "qprocsoff disables the put and service routines of the driver * or module... When the routines are disabled in a module, messages * flow around the module as if it were not present in the stream. * qprocsoff must be called by the close routine of a driver or module * before deallocating any resources on which the driver/module's * put and service routines depend. qprocsoff will remove the * queue's service routines from the list of service routines to be * run and waits until any concurrent put or service routines are * finished." * * Note that after calling qprocsoff a module/driver could itself cause its * put procedures to be run by using put(). */ void qprocsoff(queue_t *q) { ASSERT(q->q_flag & QREADR); if (q->q_flag & QWCLOSE) { /* Called more than once */ return; } disable_svc(q); removeq(q); } /* * "freezestr() freezes the state of the entire STREAM containing * the queue pair q. A frozen STREAM blocks any thread * attempting to enter any open, close, put or service routine * belonging to any queue instance in the STREAM, and blocks * any thread currently within the STREAM if it attempts to put * messages onto or take messages off of any queue within the * STREAM (with the sole exception of the caller). Threads * blocked by this mechanism remain so until the STREAM is * thawed by a call to unfreezestr(). * * Use strblock to set SQ_FROZEN in all syncqs in the stream (prevents * further entry into put, service, open, and close procedures) and * grab (and hold) all the QLOCKs in the stream (to block putq, getq etc.) * * Note: this has to be the only code that acquires one QLOCK while holding * another QLOCK (otherwise we would have locking hirarchy/ordering violations.) */ void freezestr(queue_t *q) { struct stdata *stp = STREAM(q); /* * Increment refcnt to prevent q_next from changing during the strblock * as well as while the stream is frozen. */ claimstr(RD(q)); strblock(q); ASSERT(stp->sd_freezer == NULL); stp->sd_freezer = curthread; for (q = stp->sd_wrq; q != NULL; q = SAMESTR(q) ? q->q_next : NULL) { mutex_enter(QLOCK(q)); mutex_enter(QLOCK(RD(q))); } } /* * Undo what freezestr did. * Have to drop the QLOCKs before the strunblock since strunblock will * potentially call other put procedures. */ void unfreezestr(queue_t *q) { struct stdata *stp = STREAM(q); queue_t *q1; for (q1 = stp->sd_wrq; q1 != NULL; q1 = SAMESTR(q1) ? q1->q_next : NULL) { mutex_exit(QLOCK(q1)); mutex_exit(QLOCK(RD(q1))); } ASSERT(stp->sd_freezer == curthread); stp->sd_freezer = NULL; strunblock(q); releasestr(RD(q)); } /* * Used by open and close procedures to "sleep" waiting for messages to * arrive. Note: can only be used in open and close procedures. * * Lower the gate and let in either messages on the syncq (if there are * any) or put/service procedures. * * If the queue has an outer perimeter this will not prevent entry into this * syncq (since outer_enter does not set SQ_WRITER on the syncq that gets the * exclusive access to the outer perimeter.) * * Return 0 is the cv_wait_sig was interrupted; otherwise 1. * * It only makes sense to grab sq_putlocks for !SQ_CIOC sync queues because * otherwise put entry points were not blocked in the first place. if this is * SQ_CIOC then qwait is used to wait for service procedure to run since syncq * is always SQ_CIPUT if it is SQ_CIOC. * * Note that SQ_EXCL is dropped and SQ_WANTEXITWAKEUP set in sq_flags * atomically under sq_putlocks to make sure putnext will not miss a pending * wakeup. */ int qwait_sig(queue_t *q) { syncq_t *sq, *outer; uint_t flags; int ret = 1; int is_sq_cioc; /* * Perform the same operations as a leavesq(sq, SQ_OPENCLOSE) * while detecting all cases where the perimeter is entered * so that qwait_sig can return to the caller. * * Drain the syncq if possible. Otherwise reset SQ_EXCL and * wait for a thread to leave the syncq. */ sq = q->q_syncq; ASSERT(sq); is_sq_cioc = (sq->sq_type & SQ_CIOC) ? 1 : 0; ASSERT(sq->sq_outer == NULL || sq->sq_outer->sq_flags & SQ_WRITER); outer = sq->sq_outer; /* * XXX this does not work if there is only an outer perimeter. * The semantics of qwait/qwait_sig are undefined in this case. */ if (outer) outer_exit(outer); mutex_enter(SQLOCK(sq)); if (is_sq_cioc == 0) { SQ_PUTLOCKS_ENTER(sq); } flags = sq->sq_flags; /* * Drop SQ_EXCL and sq_count but hold the SQLOCK * to prevent any undetected entry and exit into the perimeter. */ ASSERT(sq->sq_count > 0); sq->sq_count--; if (is_sq_cioc == 0) { ASSERT(flags & SQ_EXCL); flags &= ~SQ_EXCL; } /* * Unblock any thread blocked in an entersq or outer_enter. * Note: we do not unblock a thread waiting in qwait/qwait_sig, * since that could lead to livelock with two threads in * qwait for the same (per module) inner perimeter. */ if (flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); flags &= ~SQ_WANTWAKEUP; } sq->sq_flags = flags; if ((flags & SQ_QUEUED) && !(flags & SQ_STAYAWAY)) { if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } /* drain_syncq() drops SQLOCK */ drain_syncq(sq); ASSERT(MUTEX_NOT_HELD(SQLOCK(sq))); entersq(sq, SQ_OPENCLOSE); return (1); } /* * Sleep on sq_exitwait to only be woken up when threads leave the * put or service procedures. We can not sleep on sq_wait since an * outer_exit in a qwait running in the same outer perimeter would * cause a livelock "ping-pong" between two or more qwait'ers. */ do { sq->sq_flags |= SQ_WANTEXWAKEUP; if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } ret = cv_wait_sig(&sq->sq_exitwait, SQLOCK(sq)); if (is_sq_cioc == 0) { SQ_PUTLOCKS_ENTER(sq); } } while (ret && (sq->sq_flags & SQ_WANTEXWAKEUP)); if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } mutex_exit(SQLOCK(sq)); /* * Re-enter the perimeters again */ entersq(sq, SQ_OPENCLOSE); return (ret); } /* * Used by open and close procedures to "sleep" waiting for messages to * arrive. Note: can only be used in open and close procedures. * * Lower the gate and let in either messages on the syncq (if there are * any) or put/service procedures. * * If the queue has an outer perimeter this will not prevent entry into this * syncq (since outer_enter does not set SQ_WRITER on the syncq that gets the * exclusive access to the outer perimeter.) * * It only makes sense to grab sq_putlocks for !SQ_CIOC sync queues because * otherwise put entry points were not blocked in the first place. if this is * SQ_CIOC then qwait is used to wait for service procedure to run since syncq * is always SQ_CIPUT if it is SQ_CIOC. * * Note that SQ_EXCL is dropped and SQ_WANTEXITWAKEUP set in sq_flags * atomically under sq_putlocks to make sure putnext will not miss a pending * wakeup. */ void qwait(queue_t *q) { syncq_t *sq, *outer; uint_t flags; int is_sq_cioc; /* * Perform the same operations as a leavesq(sq, SQ_OPENCLOSE) * while detecting all cases where the perimeter is entered * so that qwait can return to the caller. * * Drain the syncq if possible. Otherwise reset SQ_EXCL and * wait for a thread to leave the syncq. */ sq = q->q_syncq; ASSERT(sq); is_sq_cioc = (sq->sq_type & SQ_CIOC) ? 1 : 0; ASSERT(sq->sq_outer == NULL || sq->sq_outer->sq_flags & SQ_WRITER); outer = sq->sq_outer; /* * XXX this does not work if there is only an outer perimeter. * The semantics of qwait/qwait_sig are undefined in this case. */ if (outer) outer_exit(outer); mutex_enter(SQLOCK(sq)); if (is_sq_cioc == 0) { SQ_PUTLOCKS_ENTER(sq); } flags = sq->sq_flags; /* * Drop SQ_EXCL and sq_count but hold the SQLOCK * to prevent any undetected entry and exit into the perimeter. */ ASSERT(sq->sq_count > 0); sq->sq_count--; if (is_sq_cioc == 0) { ASSERT(flags & SQ_EXCL); flags &= ~SQ_EXCL; } /* * Unblock any thread blocked in an entersq or outer_enter. * Note: we do not unblock a thread waiting in qwait/qwait_sig, * since that could lead to livelock with two threads in * qwait for the same (per module) inner perimeter. */ if (flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); flags &= ~SQ_WANTWAKEUP; } sq->sq_flags = flags; if ((flags & SQ_QUEUED) && !(flags & SQ_STAYAWAY)) { if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } /* drain_syncq() drops SQLOCK */ drain_syncq(sq); ASSERT(MUTEX_NOT_HELD(SQLOCK(sq))); entersq(sq, SQ_OPENCLOSE); return; } /* * Sleep on sq_exitwait to only be woken up when threads leave the * put or service procedures. We can not sleep on sq_wait since an * outer_exit in a qwait running in the same outer perimeter would * cause a livelock "ping-pong" between two or more qwait'ers. */ do { sq->sq_flags |= SQ_WANTEXWAKEUP; if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } cv_wait(&sq->sq_exitwait, SQLOCK(sq)); if (is_sq_cioc == 0) { SQ_PUTLOCKS_ENTER(sq); } } while (sq->sq_flags & SQ_WANTEXWAKEUP); if (is_sq_cioc == 0) { SQ_PUTLOCKS_EXIT(sq); } mutex_exit(SQLOCK(sq)); /* * Re-enter the perimeters again */ entersq(sq, SQ_OPENCLOSE); } /* * Used for the synchronous streams entrypoints when sleeping outside * the perimeters. Must never be called from regular put entrypoint. * * There's no need to grab sq_putlocks here (which only exist for CIPUT sync * queues). If it is CIPUT sync queue put entry points were not blocked in the * first place by rwnext/infonext which are treated as put entrypoints for * permiter syncronization purposes. * * Consolidation private. */ boolean_t qwait_rw(queue_t *q) { syncq_t *sq; ulong_t flags; boolean_t gotsignal = B_FALSE; /* * Perform the same operations as a leavesq(sq, SQ_PUT) * while detecting all cases where the perimeter is entered * so that qwait_rw can return to the caller. * * Drain the syncq if possible. Otherwise reset SQ_EXCL and * wait for a thread to leave the syncq. */ sq = q->q_syncq; ASSERT(sq); mutex_enter(SQLOCK(sq)); flags = sq->sq_flags; /* * Drop SQ_EXCL and sq_count but hold the SQLOCK until to prevent any * undetected entry and exit into the perimeter. */ ASSERT(sq->sq_count > 0); sq->sq_count--; if (!(sq->sq_type & SQ_CIPUT)) { ASSERT(flags & SQ_EXCL); flags &= ~SQ_EXCL; } /* * Unblock any thread blocked in an entersq or outer_enter. * Note: we do not unblock a thread waiting in qwait/qwait_sig, * since that could lead to livelock with two threads in * qwait for the same (per module) inner perimeter. */ if (flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); flags &= ~SQ_WANTWAKEUP; } sq->sq_flags = flags; if ((flags & SQ_QUEUED) && !(flags & SQ_STAYAWAY)) { /* drain_syncq() drops SQLOCK */ drain_syncq(sq); ASSERT(MUTEX_NOT_HELD(SQLOCK(sq))); entersq(sq, SQ_PUT); return (B_FALSE); } /* * Sleep on sq_exitwait to only be woken up when threads leave the * put or service procedures. We can not sleep on sq_wait since an * outer_exit in a qwait running in the same outer perimeter would * cause a livelock "ping-pong" between two or more qwait'ers. */ do { sq->sq_flags |= SQ_WANTEXWAKEUP; if (cv_wait_sig(&sq->sq_exitwait, SQLOCK(sq)) <= 0) { sq->sq_flags &= ~SQ_WANTEXWAKEUP; gotsignal = B_TRUE; break; } } while (sq->sq_flags & SQ_WANTEXWAKEUP); mutex_exit(SQLOCK(sq)); /* * Re-enter the perimeters again */ entersq(sq, SQ_PUT); return (gotsignal); } /* * Asynchronously upgrade to exclusive access at either the inner or * outer perimeter. */ void qwriter(queue_t *q, mblk_t *mp, void (*func)(), int perim) { if (perim == PERIM_INNER) qwriter_inner(q, mp, func); else if (perim == PERIM_OUTER) qwriter_outer(q, mp, func); else panic("qwriter: wrong \"perimeter\" parameter"); } /* * Schedule a synchronous streams timeout */ timeout_id_t qtimeout(queue_t *q, void (*func)(void *), void *arg, clock_t tim) { syncq_t *sq; callbparams_t *cbp; timeout_id_t tid; sq = q->q_syncq; /* * you don't want the timeout firing before its params are set up * callbparams_alloc() acquires SQLOCK(sq) * qtimeout() can't fail and can't sleep, so panic if memory is not * available. */ cbp = callbparams_alloc(sq, func, arg, KM_NOSLEEP | KM_PANIC); /* * the callbflags in the sq use the same flags. They get anded * in the callbwrapper to determine if a qun* of this callback type * is required. This is not a request to cancel. */ cbp->cbp_flags = SQ_CANCEL_TOUT; /* check new timeout version return codes */ tid = timeout(qcallbwrapper, cbp, tim); cbp->cbp_id = (callbparams_id_t)tid; mutex_exit(SQLOCK(sq)); /* use local id because the cbp memory could be free by now */ return (tid); } bufcall_id_t qbufcall(queue_t *q, size_t size, uint_t pri, void (*func)(void *), void *arg) { syncq_t *sq; callbparams_t *cbp; bufcall_id_t bid; sq = q->q_syncq; /* * you don't want the timeout firing before its params are set up * callbparams_alloc() acquires SQLOCK(sq) if successful. */ cbp = callbparams_alloc(sq, func, arg, KM_NOSLEEP); if (cbp == NULL) return ((bufcall_id_t)0); /* * the callbflags in the sq use the same flags. They get anded * in the callbwrapper to determine if a qun* of this callback type * is required. This is not a request to cancel. */ cbp->cbp_flags = SQ_CANCEL_BUFCALL; /* check new timeout version return codes */ bid = bufcall(size, pri, qcallbwrapper, cbp); cbp->cbp_id = (callbparams_id_t)bid; if (bid == 0) { callbparams_free(sq, cbp); } mutex_exit(SQLOCK(sq)); /* use local id because the params memory could be free by now */ return (bid); } /* * cancel a timeout callback which enters the inner perimeter. * cancelling of all callback types on a given syncq is serialized. * the SQ_CALLB_BYPASSED flag indicates that the callback fn did * not execute. The quntimeout return value needs to reflect this. * As with out existing callback programming model - callbacks must * be cancelled before a close completes - so ensuring that the sq * is valid when the callback wrapper is executed. */ clock_t quntimeout(queue_t *q, timeout_id_t id) { syncq_t *sq = q->q_syncq; clock_t ret; mutex_enter(SQLOCK(sq)); /* callbacks are processed serially on each syncq */ while (sq->sq_callbflags & SQ_CALLB_CANCEL_MASK) { sq->sq_flags |= SQ_WANTWAKEUP; cv_wait(&sq->sq_wait, SQLOCK(sq)); } sq->sq_cancelid = (callbparams_id_t)id; sq->sq_callbflags = SQ_CANCEL_TOUT; if (sq->sq_flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); sq->sq_flags &= ~SQ_WANTWAKEUP; } mutex_exit(SQLOCK(sq)); ret = untimeout(id); mutex_enter(SQLOCK(sq)); if (ret != -1) { /* The wrapper was never called - need to free based on id */ callbparams_free_id(sq, (callbparams_id_t)id, SQ_CANCEL_TOUT); } if (sq->sq_callbflags & SQ_CALLB_BYPASSED) { ret = 0; /* this was how much time left */ } sq->sq_callbflags = 0; if (sq->sq_flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); sq->sq_flags &= ~SQ_WANTWAKEUP; } mutex_exit(SQLOCK(sq)); return (ret); } void qunbufcall(queue_t *q, bufcall_id_t id) { syncq_t *sq = q->q_syncq; mutex_enter(SQLOCK(sq)); /* callbacks are processed serially on each syncq */ while (sq->sq_callbflags & SQ_CALLB_CANCEL_MASK) { sq->sq_flags |= SQ_WANTWAKEUP; cv_wait(&sq->sq_wait, SQLOCK(sq)); } sq->sq_cancelid = (callbparams_id_t)id; sq->sq_callbflags = SQ_CANCEL_BUFCALL; if (sq->sq_flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); sq->sq_flags &= ~SQ_WANTWAKEUP; } mutex_exit(SQLOCK(sq)); unbufcall(id); mutex_enter(SQLOCK(sq)); /* * No indication from unbufcall if the callback has already run. * Always attempt to free it. */ callbparams_free_id(sq, (callbparams_id_t)id, SQ_CANCEL_BUFCALL); sq->sq_callbflags = 0; if (sq->sq_flags & SQ_WANTWAKEUP) { cv_broadcast(&sq->sq_wait); sq->sq_flags &= ~SQ_WANTWAKEUP; } mutex_exit(SQLOCK(sq)); } /* * Associate the stream with an instance of the bottom driver. This * function is called by APIs that establish or modify the hardware * association (ppa) of an open stream. Two examples of such * post-open(9E) APIs are the dlpi(4P) DL_ATTACH_REQ message, and the * ndd(8) "instance=" ioctl(2). This interface may be called from a * stream driver's wput procedure and from within syncq perimeters, * so it can't block. * * The qassociate() "model" is that it should drive attach(9E), yet it * can't really do that because driving attach(9E) is a blocking * operation. Instead, the qassociate() implementation has complex * dependencies on the implementation behavior of other parts of the * kernel to ensure all appropriate instances (ones that have not been * made inaccessible by DR) are attached at stream open() time, and * that they will not autodetach. The code relies on the fact that an * open() of a stream that ends up using qassociate() always occurs on * a minor node created with CLONE_DEV. The open() comes through * clnopen() and since clnopen() calls ddi_hold_installed_driver() we * attach all instances and mark them DN_NO_AUTODETACH (given * DN_DRIVER_HELD is maintained correctly). * * Since qassociate() can't really drive attach(9E), there are corner * cases where the compromise described above leads to qassociate() * returning failure. This can happen when administrative functions * that cause detach(9E), such as "update_drv" or "modunload -i", are * performed on the driver between the time the stream was opened and * the time its hardware association was established. Although this can * theoretically be an arbitrary amount of time, in practice the window * is usually quite small, since applications almost always issue their * hardware association request immediately after opening the stream, * and do not typically switch association while open. When these * corner cases occur, and qassociate() finds the requested instance * detached, it will return failure. This failure should be propagated * to the requesting administrative application using the appropriate * post-open(9E) API error mechanism. * * All qassociate() callers are expected to check for and gracefully handle * failure return, propagating errors back to the requesting administrative * application. */ int qassociate(queue_t *q, int instance) { vnode_t *vp; major_t major; dev_info_t *dip; if (instance == -1) { ddi_assoc_queue_with_devi(q, NULL); return (0); } vp = STREAM(q)->sd_vnode; major = getmajor(vp->v_rdev); dip = ddi_hold_devi_by_instance(major, instance, E_DDI_HOLD_DEVI_NOATTACH); if (dip == NULL) return (-1); ddi_assoc_queue_with_devi(q, dip); ddi_release_devi(dip); return (0); } /* * This routine is the SVR4MP 'replacement' for * hat_getkpfnum. The only major difference is * the return value for illegal addresses - since * sunm_getkpfnum() and srmmu_getkpfnum() both * return '-1' for bogus mappings, we can (more or * less) return the value directly. */ ppid_t kvtoppid(caddr_t addr) { return ((ppid_t)hat_getpfnum(kas.a_hat, addr)); } /* * This is used to set the timeout value for cv_timed_wait() or * cv_timedwait_sig(). */ void time_to_wait(clock_t *now, clock_t time) { *now = ddi_get_lbolt() + time; }