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/* $Id: semeventmulti-r0drv-darwin.cpp $ */
/** @file
* IPRT - Multiple Release Event Semaphores, Ring-0 Driver, Darwin.
*/
/*
* 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.
*/
/*********************************************************************************************************************************
* Header Files *
*********************************************************************************************************************************/
#define RTSEMEVENTMULTI_WITHOUT_REMAPPING
#include "the-darwin-kernel.h"
#include "internal/iprt.h"
#include <iprt/semaphore.h>
#include <iprt/assert.h>
#include <iprt/asm.h>
#if defined(RT_ARCH_AMD64) || defined(RT_ARCH_X86)
# include <iprt/asm-amd64-x86.h>
#endif
#include <iprt/err.h>
#include <iprt/lockvalidator.h>
#include <iprt/mem.h>
#include <iprt/mp.h>
#include <iprt/thread.h>
#include <iprt/time.h>
#include "internal/magics.h"
/*********************************************************************************************************************************
* Defined Constants And Macros *
*********************************************************************************************************************************/
/** @name fStateAndGen values
* @{ */
/** The state bit number. */
#define RTSEMEVENTMULTIDARWIN_STATE_BIT 0
/** The state mask. */
#define RTSEMEVENTMULTIDARWIN_STATE_MASK RT_BIT_32(RTSEMEVENTMULTIDARWIN_STATE_BIT)
/** The generation mask. */
#define RTSEMEVENTMULTIDARWIN_GEN_MASK ~RTSEMEVENTMULTIDARWIN_STATE_MASK
/** The generation shift. */
#define RTSEMEVENTMULTIDARWIN_GEN_SHIFT 1
/** The initial variable value. */
#define RTSEMEVENTMULTIDARWIN_STATE_GEN_INIT UINT32_C(0xfffffffc)
/** @} */
/*********************************************************************************************************************************
* Structures and Typedefs *
*********************************************************************************************************************************/
/**
* Darwin multiple release event semaphore.
*/
typedef struct RTSEMEVENTMULTIINTERNAL
{
/** Magic value (RTSEMEVENTMULTI_MAGIC). */
uint32_t volatile u32Magic;
/** The object state bit and generation counter.
* The generation counter is incremented every time the object is
* signalled. */
uint32_t volatile fStateAndGen;
/** Reference counter. */
uint32_t volatile cRefs;
/** Set if there are blocked threads. */
bool volatile fHaveBlockedThreads;
/** The spinlock protecting us. */
lck_spin_t *pSpinlock;
} RTSEMEVENTMULTIINTERNAL, *PRTSEMEVENTMULTIINTERNAL;
RTDECL(int) RTSemEventMultiCreate(PRTSEMEVENTMULTI phEventMultiSem)
{
return RTSemEventMultiCreateEx(phEventMultiSem, 0 /*fFlags*/, NIL_RTLOCKVALCLASS, NULL);
}
RTDECL(int) RTSemEventMultiCreateEx(PRTSEMEVENTMULTI phEventMultiSem, uint32_t fFlags, RTLOCKVALCLASS hClass,
const char *pszNameFmt, ...)
{
RT_NOREF(hClass, pszNameFmt);
AssertReturn(!(fFlags & ~RTSEMEVENTMULTI_FLAGS_NO_LOCK_VAL), VERR_INVALID_PARAMETER);
AssertCompile(sizeof(RTSEMEVENTMULTIINTERNAL) > sizeof(void *));
AssertPtrReturn(phEventMultiSem, VERR_INVALID_POINTER);
RT_ASSERT_PREEMPTIBLE();
IPRT_DARWIN_SAVE_EFL_AC();
PRTSEMEVENTMULTIINTERNAL pThis = (PRTSEMEVENTMULTIINTERNAL)RTMemAlloc(sizeof(*pThis));
if (pThis)
{
pThis->u32Magic = RTSEMEVENTMULTI_MAGIC;
pThis->fStateAndGen = RTSEMEVENTMULTIDARWIN_STATE_GEN_INIT;
pThis->cRefs = 1;
pThis->fHaveBlockedThreads = false;
Assert(g_pDarwinLockGroup);
pThis->pSpinlock = lck_spin_alloc_init(g_pDarwinLockGroup, LCK_ATTR_NULL);
if (pThis->pSpinlock)
{
*phEventMultiSem = pThis;
IPRT_DARWIN_RESTORE_EFL_AC();
return VINF_SUCCESS;
}
pThis->u32Magic = 0;
RTMemFree(pThis);
}
IPRT_DARWIN_RESTORE_EFL_AC();
return VERR_NO_MEMORY;
}
/**
* Retain a reference to the semaphore.
*
* @param pThis The semaphore.
*/
DECLINLINE(void) rtR0SemEventMultiDarwinRetain(PRTSEMEVENTMULTIINTERNAL pThis)
{
uint32_t cRefs = ASMAtomicIncU32(&pThis->cRefs);
Assert(cRefs && cRefs < 100000);
RT_NOREF_PV(cRefs);
}
/**
* Release a reference, destroy the thing if necessary.
*
* @param pThis The semaphore.
*/
DECLINLINE(void) rtR0SemEventMultiDarwinRelease(PRTSEMEVENTMULTIINTERNAL pThis)
{
if (RT_UNLIKELY(ASMAtomicDecU32(&pThis->cRefs) == 0))
{
IPRT_DARWIN_SAVE_EFL_AC();
Assert(pThis->u32Magic != RTSEMEVENTMULTI_MAGIC);
lck_spin_destroy(pThis->pSpinlock, g_pDarwinLockGroup);
RTMemFree(pThis);
IPRT_DARWIN_RESTORE_EFL_AC();
}
}
RTDECL(int) RTSemEventMultiDestroy(RTSEMEVENTMULTI hEventMultiSem)
{
PRTSEMEVENTMULTIINTERNAL pThis = (PRTSEMEVENTMULTIINTERNAL)hEventMultiSem;
if (pThis == NIL_RTSEMEVENTMULTI)
return VINF_SUCCESS;
AssertPtrReturn(pThis, VERR_INVALID_HANDLE);
AssertMsgReturn(pThis->u32Magic == RTSEMEVENTMULTI_MAGIC, ("pThis=%p u32Magic=%#x\n", pThis, pThis->u32Magic), VERR_INVALID_HANDLE);
Assert(pThis->cRefs > 0);
RT_ASSERT_INTS_ON();
IPRT_DARWIN_SAVE_EFL_AC();
RTCCUINTREG const fIntSaved = ASMIntDisableFlags();
lck_spin_lock(pThis->pSpinlock);
ASMAtomicWriteU32(&pThis->u32Magic, ~RTSEMEVENTMULTI_MAGIC); /* make the handle invalid */
ASMAtomicAndU32(&pThis->fStateAndGen, RTSEMEVENTMULTIDARWIN_GEN_MASK);
if (pThis->fHaveBlockedThreads)
{
/* abort waiting threads. */
thread_wakeup_prim((event_t)pThis, FALSE /* all threads */, THREAD_RESTART);
}
lck_spin_unlock(pThis->pSpinlock);
ASMSetFlags(fIntSaved);
rtR0SemEventMultiDarwinRelease(pThis);
IPRT_DARWIN_RESTORE_EFL_AC();
return VINF_SUCCESS;
}
RTDECL(int) RTSemEventMultiSignal(RTSEMEVENTMULTI hEventMultiSem)
{
PRTSEMEVENTMULTIINTERNAL pThis = (PRTSEMEVENTMULTIINTERNAL)hEventMultiSem;
AssertPtrReturn(pThis, VERR_INVALID_HANDLE);
AssertMsgReturn(pThis->u32Magic == RTSEMEVENTMULTI_MAGIC, ("pThis=%p u32Magic=%#x\n", pThis, pThis->u32Magic), VERR_INVALID_HANDLE);
RT_ASSERT_PREEMPT_CPUID_VAR();
/*
* Coming here with interrupts disabled should be okay. The thread_wakeup_prim KPI is used
* by the interrupt handler IOFilterInterruptEventSource::disableInterruptOccurred() via
* signalWorkAvailable(). The only problem is if we have to destroy the event structure,
* as RTMemFree does not work with interrupts disabled (IOFree/kfree takes zone mutex).
*/
//RT_ASSERT_INTS_ON(); - we may be called from interrupt context, which seems to be perfectly fine if we disable interrupts.
IPRT_DARWIN_SAVE_EFL_AC();
RTCCUINTREG const fIntSaved = ASMIntDisableFlags();
rtR0SemEventMultiDarwinRetain(pThis);
lck_spin_lock(pThis->pSpinlock);
/*
* Set the signal and increment the generation counter.
*/
uint32_t fNew = ASMAtomicUoReadU32(&pThis->fStateAndGen);
fNew += 1 << RTSEMEVENTMULTIDARWIN_GEN_SHIFT;
fNew |= RTSEMEVENTMULTIDARWIN_STATE_MASK;
ASMAtomicWriteU32(&pThis->fStateAndGen, fNew);
/*
* Wake up all sleeping threads.
*/
if (pThis->fHaveBlockedThreads)
{
ASMAtomicWriteBool(&pThis->fHaveBlockedThreads, false);
thread_wakeup_prim((event_t)pThis, FALSE /* all threads */, THREAD_AWAKENED);
}
lck_spin_unlock(pThis->pSpinlock);
ASMSetFlags(fIntSaved);
rtR0SemEventMultiDarwinRelease(pThis);
RT_ASSERT_PREEMPT_CPUID();
AssertMsg((fSavedEfl & X86_EFL_IF) == (ASMGetFlags() & X86_EFL_IF), ("fSavedEfl=%#x cur=%#x\n",(uint32_t)fSavedEfl, ASMGetFlags()));
IPRT_DARWIN_RESTORE_EFL_AC();
return VINF_SUCCESS;
}
RTDECL(int) RTSemEventMultiReset(RTSEMEVENTMULTI hEventMultiSem)
{
PRTSEMEVENTMULTIINTERNAL pThis = (PRTSEMEVENTMULTIINTERNAL)hEventMultiSem;
AssertPtrReturn(pThis, VERR_INVALID_HANDLE);
AssertMsgReturn(pThis->u32Magic == RTSEMEVENTMULTI_MAGIC, ("pThis=%p u32Magic=%#x\n", pThis, pThis->u32Magic), VERR_INVALID_HANDLE);
RT_ASSERT_PREEMPT_CPUID_VAR();
RT_ASSERT_INTS_ON();
IPRT_DARWIN_SAVE_EFL_AC();
RTCCUINTREG const fIntSaved = ASMIntDisableFlags();
rtR0SemEventMultiDarwinRetain(pThis);
lck_spin_lock(pThis->pSpinlock);
ASMAtomicAndU32(&pThis->fStateAndGen, ~RTSEMEVENTMULTIDARWIN_STATE_MASK);
lck_spin_unlock(pThis->pSpinlock);
ASMSetFlags(fIntSaved);
rtR0SemEventMultiDarwinRelease(pThis);
RT_ASSERT_PREEMPT_CPUID();
IPRT_DARWIN_RESTORE_EFL_AC();
return VINF_SUCCESS;
}
/**
* Worker for RTSemEventMultiWaitEx and RTSemEventMultiWaitExDebug.
*
* @returns VBox status code.
* @param pThis The event semaphore.
* @param fFlags See RTSemEventMultiWaitEx.
* @param uTimeout See RTSemEventMultiWaitEx.
* @param pSrcPos The source code position of the wait.
*/
static int rtR0SemEventMultiDarwinWait(PRTSEMEVENTMULTIINTERNAL pThis, uint32_t fFlags, uint64_t uTimeout,
PCRTLOCKVALSRCPOS pSrcPos)
{
RT_NOREF(pSrcPos);
/*
* Validate input.
*/
AssertPtrReturn(pThis, VERR_INVALID_HANDLE);
AssertMsgReturn(pThis->u32Magic == RTSEMEVENTMULTI_MAGIC, ("pThis=%p u32Magic=%#x\n", pThis, pThis->u32Magic), VERR_INVALID_HANDLE);
AssertReturn(RTSEMWAIT_FLAGS_ARE_VALID(fFlags), VERR_INVALID_PARAMETER);
if (uTimeout != 0 || (fFlags & RTSEMWAIT_FLAGS_INDEFINITE))
RT_ASSERT_PREEMPTIBLE();
IPRT_DARWIN_SAVE_EFL_AC();
RTCCUINTREG const fIntSaved = ASMIntDisableFlags();
rtR0SemEventMultiDarwinRetain(pThis);
lck_spin_lock(pThis->pSpinlock);
/*
* Is the event already signalled or do we have to wait?
*/
int rc;
uint32_t const fOrgStateAndGen = ASMAtomicUoReadU32(&pThis->fStateAndGen);
if (fOrgStateAndGen & RTSEMEVENTMULTIDARWIN_STATE_MASK)
rc = VINF_SUCCESS;
else
{
/*
* We have to wait. So, we'll need to convert the timeout and figure
* out if it's indefinite or not.
*/
uint64_t uNsAbsTimeout = 1;
if (!(fFlags & RTSEMWAIT_FLAGS_INDEFINITE))
{
if (fFlags & RTSEMWAIT_FLAGS_MILLISECS)
uTimeout = uTimeout < UINT64_MAX / UINT32_C(1000000) * UINT32_C(1000000)
? uTimeout * UINT32_C(1000000)
: UINT64_MAX;
if (uTimeout == UINT64_MAX)
fFlags |= RTSEMWAIT_FLAGS_INDEFINITE;
else
{
uint64_t u64Now;
if (fFlags & RTSEMWAIT_FLAGS_RELATIVE)
{
if (uTimeout != 0)
{
u64Now = RTTimeSystemNanoTS();
uNsAbsTimeout = u64Now + uTimeout;
if (uNsAbsTimeout < u64Now) /* overflow */
fFlags |= RTSEMWAIT_FLAGS_INDEFINITE;
}
}
else
{
uNsAbsTimeout = uTimeout;
u64Now = RTTimeSystemNanoTS();
uTimeout = u64Now < uTimeout ? uTimeout - u64Now : 0;
}
}
}
if ( !(fFlags & RTSEMWAIT_FLAGS_INDEFINITE)
&& uTimeout == 0)
{
/*
* Poll call, we already checked the condition above so no need to
* wait for anything.
*/
rc = VERR_TIMEOUT;
}
else
{
for (;;)
{
/*
* Do the actual waiting.
*/
ASMAtomicWriteBool(&pThis->fHaveBlockedThreads, true);
wait_interrupt_t fInterruptible = fFlags & RTSEMWAIT_FLAGS_INTERRUPTIBLE ? THREAD_ABORTSAFE : THREAD_UNINT;
wait_result_t rcWait;
if (fFlags & RTSEMWAIT_FLAGS_INDEFINITE)
rcWait = lck_spin_sleep(pThis->pSpinlock, LCK_SLEEP_DEFAULT, (event_t)pThis, fInterruptible);
else
{
uint64_t u64AbsTime;
nanoseconds_to_absolutetime(uNsAbsTimeout, &u64AbsTime);
rcWait = lck_spin_sleep_deadline(pThis->pSpinlock, LCK_SLEEP_DEFAULT,
(event_t)pThis, fInterruptible, u64AbsTime);
}
/*
* Deal with the wait result.
*/
if (RT_LIKELY(pThis->u32Magic == RTSEMEVENTMULTI_MAGIC))
{
switch (rcWait)
{
case THREAD_AWAKENED:
if (RT_LIKELY(ASMAtomicUoReadU32(&pThis->fStateAndGen) != fOrgStateAndGen))
rc = VINF_SUCCESS;
else if (fFlags & RTSEMWAIT_FLAGS_INTERRUPTIBLE)
rc = VERR_INTERRUPTED;
else
continue; /* Seen this happen after fork/exec/something. */
break;
case THREAD_TIMED_OUT:
Assert(!(fFlags & RTSEMWAIT_FLAGS_INDEFINITE));
rc = VERR_TIMEOUT;
break;
case THREAD_INTERRUPTED:
Assert(fInterruptible != THREAD_UNINT);
rc = VERR_INTERRUPTED;
break;
case THREAD_RESTART:
AssertMsg(pThis->u32Magic == ~RTSEMEVENTMULTI_MAGIC, ("%#x\n", pThis->u32Magic));
rc = VERR_SEM_DESTROYED;
break;
default:
AssertMsgFailed(("rcWait=%d\n", rcWait));
rc = VERR_INTERNAL_ERROR_3;
break;
}
}
else
rc = VERR_SEM_DESTROYED;
break;
}
}
}
lck_spin_unlock(pThis->pSpinlock);
ASMSetFlags(fIntSaved);
rtR0SemEventMultiDarwinRelease(pThis);
IPRT_DARWIN_RESTORE_EFL_AC();
return rc;
}
RTDECL(int) RTSemEventMultiWaitEx(RTSEMEVENTMULTI hEventMultiSem, uint32_t fFlags, uint64_t uTimeout)
{
#ifndef RTSEMEVENT_STRICT
return rtR0SemEventMultiDarwinWait(hEventMultiSem, fFlags, uTimeout, NULL);
#else
RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_NORMAL_API();
return rtR0SemEventMultiDarwinWait(hEventMultiSem, fFlags, uTimeout, &SrcPos);
#endif
}
RTDECL(int) RTSemEventMultiWaitExDebug(RTSEMEVENTMULTI hEventMultiSem, uint32_t fFlags, uint64_t uTimeout,
RTHCUINTPTR uId, RT_SRC_POS_DECL)
{
RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_DEBUG_API();
return rtR0SemEventMultiDarwinWait(hEventMultiSem, fFlags, uTimeout, &SrcPos);
}
RTDECL(uint32_t) RTSemEventMultiGetResolution(void)
{
uint64_t cNs;
absolutetime_to_nanoseconds(1, &cNs);
return (uint32_t)cNs ? (uint32_t)cNs : 0;
}
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