/* $Id: semeventwait-r0drv-solaris.h 76585 2019-01-01 06:31:29Z vboxsync $ */ /** @file * IPRT - Solaris Ring-0 Driver Helpers for Event Semaphore Waits. */ /* * Copyright (C) 2006-2019 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ #ifndef IPRT_INCLUDED_SRC_r0drv_solaris_semeventwait_r0drv_solaris_h #define IPRT_INCLUDED_SRC_r0drv_solaris_semeventwait_r0drv_solaris_h #ifndef RT_WITHOUT_PRAGMA_ONCE # pragma once #endif #include "the-solaris-kernel.h" #include #include #include /** The resolution (nanoseconds) specified when using timeout_generic. */ #define RTR0SEMSOLWAIT_RESOLUTION 50000 /** Disables the cyclic fallback code for old S10 installs - see @bugref{5342}. * @todo Fixed by @bugref{5595}, can be reenabled after checking out * CY_HIGH_LEVEL. */ #define RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK #define SOL_THREAD_TINTR_PTR ((kthread_t **)((char *)curthread + g_offrtSolThreadIntrThread)) /** * Solaris semaphore wait structure. */ typedef struct RTR0SEMSOLWAIT { /** The absolute timeout given as nanoseconds since the start of the * monotonic clock. */ uint64_t uNsAbsTimeout; /** The timeout in nanoseconds relative to the start of the wait. */ uint64_t cNsRelTimeout; /** The native timeout value. */ union { /** The timeout (in ticks) when fHighRes is false. */ clock_t lTimeout; } u; /** Set if we use high resolution timeouts. */ bool fHighRes; /** Set if it's an indefinite wait. */ bool fIndefinite; /** Set if the waiting thread is ready to be woken up. * Avoids false setrun() calls due to temporary mutex exits. */ bool volatile fWantWakeup; /** Set if we've already timed out. * Set by rtR0SemSolWaitDoIt or rtR0SemSolWaitHighResTimeout, read by * rtR0SemSolWaitHasTimedOut. */ bool volatile fTimedOut; /** Whether the wait was interrupted. */ bool fInterrupted; /** Interruptible or uninterruptible wait. */ bool fInterruptible; /** The thread to wake up. */ kthread_t *pThread; #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK /** Cylic timer ID (used by the timeout callback). */ cyclic_id_t idCy; #endif /** The mutex associated with the condition variable wait. */ void volatile *pvMtx; } RTR0SEMSOLWAIT; /** Pointer to a solaris semaphore wait structure. */ typedef RTR0SEMSOLWAIT *PRTR0SEMSOLWAIT; /** * Initializes a wait. * * The caller MUST check the wait condition BEFORE calling this function or the * timeout logic will be flawed. * * @returns VINF_SUCCESS or VERR_TIMEOUT. * @param pWait The wait structure. * @param fFlags The wait flags. * @param uTimeout The timeout. */ DECLINLINE(int) rtR0SemSolWaitInit(PRTR0SEMSOLWAIT pWait, uint32_t fFlags, uint64_t uTimeout) { /* * Process the flags and timeout. */ if (!(fFlags & RTSEMWAIT_FLAGS_INDEFINITE)) { if (fFlags & RTSEMWAIT_FLAGS_MILLISECS) uTimeout = uTimeout < UINT64_MAX / RT_NS_1MS ? uTimeout * RT_NS_1MS : UINT64_MAX; if (uTimeout == UINT64_MAX) fFlags |= RTSEMWAIT_FLAGS_INDEFINITE; else { uint64_t u64Now; if (fFlags & RTSEMWAIT_FLAGS_RELATIVE) { if (uTimeout == 0) return VERR_TIMEOUT; u64Now = RTTimeSystemNanoTS(); pWait->cNsRelTimeout = uTimeout; pWait->uNsAbsTimeout = u64Now + uTimeout; if (pWait->uNsAbsTimeout < u64Now) /* overflow */ fFlags |= RTSEMWAIT_FLAGS_INDEFINITE; } else { u64Now = RTTimeSystemNanoTS(); if (u64Now >= uTimeout) return VERR_TIMEOUT; pWait->cNsRelTimeout = uTimeout - u64Now; pWait->uNsAbsTimeout = uTimeout; } } } if (!(fFlags & RTSEMWAIT_FLAGS_INDEFINITE)) { pWait->fIndefinite = false; if ( ( (fFlags & (RTSEMWAIT_FLAGS_NANOSECS | RTSEMWAIT_FLAGS_ABSOLUTE)) || pWait->cNsRelTimeout < UINT32_C(1000000000) / 100 /*Hz*/ * 4) #ifdef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK && g_pfnrtR0Sol_timeout_generic != NULL #endif ) pWait->fHighRes = true; else { uint64_t cTicks = NSEC_TO_TICK_ROUNDUP(uTimeout); if (cTicks >= LONG_MAX) fFlags |= RTSEMWAIT_FLAGS_INDEFINITE; else { pWait->u.lTimeout = cTicks; pWait->fHighRes = false; } } } if (fFlags & RTSEMWAIT_FLAGS_INDEFINITE) { pWait->fIndefinite = true; pWait->fHighRes = false; pWait->uNsAbsTimeout = UINT64_MAX; pWait->cNsRelTimeout = UINT64_MAX; pWait->u.lTimeout = LONG_MAX; } pWait->fWantWakeup = false; pWait->fTimedOut = false; pWait->fInterrupted = false; pWait->fInterruptible = !!(fFlags & RTSEMWAIT_FLAGS_INTERRUPTIBLE); pWait->pThread = curthread; pWait->pvMtx = NULL; #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK pWait->idCy = CYCLIC_NONE; #endif return VINF_SUCCESS; } #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK /** * Cyclic timeout callback that sets the timeout indicator and wakes up the * waiting thread. * * @param pvUser The wait structure. */ static void rtR0SemSolWaitHighResTimeout(void *pvUser) { PRTR0SEMSOLWAIT pWait = (PRTR0SEMSOLWAIT)pvUser; kthread_t *pThread = pWait->pThread; kmutex_t *pMtx = (kmutex_t *)ASMAtomicReadPtr(&pWait->pvMtx); if (VALID_PTR(pMtx)) { /* Enter the mutex here to make sure the thread has gone to sleep before we wake it up. Note: Trying to take the cpu_lock here doesn't work. */ mutex_enter(pMtx); if (mutex_owner(&cpu_lock) == curthread) { cyclic_remove(pWait->idCy); pWait->idCy = CYCLIC_NONE; } bool const fWantWakeup = pWait->fWantWakeup; ASMAtomicWriteBool(&pWait->fTimedOut, true); mutex_exit(pMtx); if (fWantWakeup) setrun(pThread); } } #endif /** * Timeout callback that sets the timeout indicator and wakes up the waiting * thread. * * @param pvUser The wait structure. */ static void rtR0SemSolWaitTimeout(void *pvUser) { PRTR0SEMSOLWAIT pWait = (PRTR0SEMSOLWAIT)pvUser; kthread_t *pThread = pWait->pThread; kmutex_t *pMtx = (kmutex_t *)ASMAtomicReadPtr((void * volatile *)&pWait->pvMtx); if (VALID_PTR(pMtx)) { /* Enter the mutex here to make sure the thread has gone to sleep before we wake it up. */ mutex_enter(pMtx); bool const fWantWakeup = pWait->fWantWakeup; ASMAtomicWriteBool(&pWait->fTimedOut, true); mutex_exit(pMtx); if (fWantWakeup) setrun(pThread); } } /** * Do the actual wait. * * @param pWait The wait structure. * @param pCnd The condition variable to wait on. * @param pMtx The mutex related to the condition variable. * The caller has entered this. * @param pfState The state variable to check if have changed * after leaving the mutex (spinlock). * @param fCurState The current value of @a pfState. We'll return * without sleeping if @a pfState doesn't hold * this value after reacquiring the mutex. * * @remarks This must be call with the object mutex (spinlock) held. */ DECLINLINE(void) rtR0SemSolWaitDoIt(PRTR0SEMSOLWAIT pWait, kcondvar_t *pCnd, kmutex_t *pMtx, uint32_t volatile *pfState, uint32_t const fCurState) { union { callout_id_t idCo; timeout_id_t idTom; } u; /* * Arm the timeout callback. * * We will have to leave the mutex (spinlock) when doing this because S10 * (didn't check S11) will not correctly preserve PIL across calls to * timeout_generic() - @bugref{5595}. We do it for all timeout methods to * be on the safe side, the nice sideeffect of which is that it solves the * lock inversion problem found in @bugref{5342}. */ bool const fHasTimeout = !pWait->fIndefinite; bool fGoToSleep = !fHasTimeout; if (fHasTimeout) { pWait->fWantWakeup = false; /* only want fTimedOut */ ASMAtomicWritePtr(&pWait->pvMtx, pMtx); /* atomic is paranoia */ mutex_exit(pMtx); if (pWait->fHighRes) { #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK if (g_pfnrtR0Sol_timeout_generic != NULL) #endif { /* * High resolution timeout - arm a high resolution timeout callback * for waking up the thread at the desired time. */ u.idCo = g_pfnrtR0Sol_timeout_generic(CALLOUT_REALTIME, rtR0SemSolWaitTimeout, pWait, pWait->uNsAbsTimeout, RTR0SEMSOLWAIT_RESOLUTION, CALLOUT_FLAG_ABSOLUTE); } #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK else { /* * High resolution timeout - arm a one-shot cyclic for waking up * the thread at the desired time. */ cyc_handler_t Cyh; Cyh.cyh_arg = pWait; Cyh.cyh_func = rtR0SemSolWaitHighResTimeout; Cyh.cyh_level = CY_LOW_LEVEL; /// @todo try CY_LOCK_LEVEL and CY_HIGH_LEVEL? cyc_time_t Cyt; Cyt.cyt_when = pWait->uNsAbsTimeout; Cyt.cyt_interval = UINT64_C(1000000000) * 60; mutex_enter(&cpu_lock); pWait->idCy = cyclic_add(&Cyh, &Cyt); mutex_exit(&cpu_lock); } #endif } else { /* * Normal timeout. * We're better off with our own callback like on the timeout man page, * than calling cv_timedwait[_sig](). */ u.idTom = realtime_timeout(rtR0SemSolWaitTimeout, pWait, pWait->u.lTimeout); } /* * Reacquire the mutex and check if the sleep condition still holds and * that we didn't already time out. */ mutex_enter(pMtx); pWait->fWantWakeup = true; fGoToSleep = !ASMAtomicUoReadBool(&pWait->fTimedOut) && ASMAtomicReadU32(pfState) == fCurState; } /* * Do the waiting if that's still desirable. * (rc > 0 - normal wake-up; rc == 0 - interruption; rc == -1 - timeout) */ if (fGoToSleep) { if (pWait->fInterruptible) { int rc = cv_wait_sig(pCnd, pMtx); if (RT_UNLIKELY(rc <= 0)) { if (RT_LIKELY(rc == 0)) pWait->fInterrupted = true; else AssertMsgFailed(("rc=%d\n", rc)); /* no timeouts, see above! */ } } else cv_wait(pCnd, pMtx); } /* * Remove the timeout callback. Drop the lock while we're doing that * to reduce lock contention / deadlocks. Before dropping the lock, * indicate that the callback shouldn't do anything. * * (Too bad we are stuck with the cv_* API here, it's doing a little * bit too much.) */ if (fHasTimeout) { pWait->fWantWakeup = false; ASMAtomicWritePtr(&pWait->pvMtx, NULL); mutex_exit(pMtx); if (pWait->fHighRes) { #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK if (g_pfnrtR0Sol_timeout_generic != NULL) #endif g_pfnrtR0Sol_untimeout_generic(u.idCo, 0 /*nowait*/); #ifndef RTR0SEMSOLWAIT_NO_OLD_S10_FALLBACK else { mutex_enter(&cpu_lock); if (pWait->idCy != CYCLIC_NONE) { cyclic_remove(pWait->idCy); pWait->idCy = CYCLIC_NONE; } mutex_exit(&cpu_lock); } #endif } else untimeout(u.idTom); mutex_enter(pMtx); } } /** * Checks if a solaris wait was interrupted. * * @returns true / false * @param pWait The wait structure. * @remarks This shall be called before the first rtR0SemSolWaitDoIt(). */ DECLINLINE(bool) rtR0SemSolWaitWasInterrupted(PRTR0SEMSOLWAIT pWait) { return pWait->fInterrupted; } /** * Checks if a solaris wait has timed out. * * @returns true / false * @param pWait The wait structure. */ DECLINLINE(bool) rtR0SemSolWaitHasTimedOut(PRTR0SEMSOLWAIT pWait) { return pWait->fTimedOut; } /** * Deletes a solaris wait. * * @param pWait The wait structure. */ DECLINLINE(void) rtR0SemSolWaitDelete(PRTR0SEMSOLWAIT pWait) { pWait->pThread = NULL; } /** * Enters the mutex, unpinning the underlying current thread if contended and * we're on an interrupt thread. * * The unpinning is done to prevent a deadlock, see s this could lead to a * deadlock (see @bugref{4259} for the full explanation) * * @param pMtx The mutex to enter. */ DECLINLINE(void) rtR0SemSolWaitEnterMutexWithUnpinningHack(kmutex_t *pMtx) { int fAcquired = mutex_tryenter(pMtx); if (!fAcquired) { /* * Note! This assumes nobody is using the RTThreadPreemptDisable() in an * interrupt context and expects it to work right. The swtch will * result in a voluntary preemption. To fix this, we would have to * do our own counting in RTThreadPreemptDisable/Restore() like we do * on systems which doesn't do preemption (OS/2, linux, ...) and * check whether preemption was disabled via RTThreadPreemptDisable() * or not and only call swtch if RTThreadPreemptDisable() wasn't called. */ kthread_t **ppIntrThread = SOL_THREAD_TINTR_PTR; if ( *ppIntrThread && getpil() < DISP_LEVEL) { RTTHREADPREEMPTSTATE PreemptState = RTTHREADPREEMPTSTATE_INITIALIZER; RTThreadPreemptDisable(&PreemptState); preempt(); RTThreadPreemptRestore(&PreemptState); } mutex_enter(pMtx); } } /** * Gets the max resolution of the timeout machinery. * * @returns Resolution specified in nanoseconds. */ DECLINLINE(uint32_t) rtR0SemSolWaitGetResolution(void) { return g_pfnrtR0Sol_timeout_generic != NULL ? RTR0SEMSOLWAIT_RESOLUTION : cyclic_getres(); } #endif /* !IPRT_INCLUDED_SRC_r0drv_solaris_semeventwait_r0drv_solaris_h */