/* $Id: semrw-generic.cpp $ */ /** @file * IPRT - Read-Write Semaphore, Generic. * * This is a generic implementation for OSes which don't have * native RW semaphores. */ /* * Copyright (C) 2006-2023 Oracle and/or its affiliates. * * This file is part of VirtualBox base platform packages, as * available from https://www.virtualbox.org. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation, in version 3 of the * License. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL), a copy of it is provided in the "COPYING.CDDL" file included * in the VirtualBox 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. * * SPDX-License-Identifier: GPL-3.0-only OR CDDL-1.0 */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define RTSEMRW_WITHOUT_REMAPPING #include #include "internal/iprt.h" #include #include #include #include #include #include #include #include #include "internal/magics.h" #include "internal/strict.h" /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /** Internal representation of a Read-Write semaphore for the * Generic implementation. */ struct RTSEMRWINTERNAL { /** The usual magic. (RTSEMRW_MAGIC) */ uint32_t u32Magic; /* Alignment padding. */ uint32_t u32Padding; /** This critical section serializes the access to and updating of the structure members. */ RTCRITSECT CritSect; /** The current number of reads. (pure read recursion counts too) */ uint32_t cReads; /** The current number of writes. (recursion counts too) */ uint32_t cWrites; /** Number of read recursions by the writer. */ uint32_t cWriterReads; /** Number of writers waiting. */ uint32_t cWritesWaiting; /** The write owner of the lock. */ RTNATIVETHREAD hWriter; /** The handle of the event object on which the waiting readers block. (manual reset). */ RTSEMEVENTMULTI ReadEvent; /** The handle of the event object on which the waiting writers block. (automatic reset). */ RTSEMEVENT WriteEvent; /** Need to reset ReadEvent. */ bool fNeedResetReadEvent; #ifdef RTSEMRW_STRICT /** The validator record for the writer. */ RTLOCKVALRECEXCL ValidatorWrite; /** The validator record for the readers. */ RTLOCKVALRECSHRD ValidatorRead; #endif }; RTDECL(int) RTSemRWCreate(PRTSEMRW phRWSem) { return RTSemRWCreateEx(phRWSem, 0 /*fFlags*/, NIL_RTLOCKVALCLASS, RTLOCKVAL_SUB_CLASS_NONE, "RTSemRW"); } RT_EXPORT_SYMBOL(RTSemRWCreate); RTDECL(int) RTSemRWCreateEx(PRTSEMRW phRWSem, uint32_t fFlags, RTLOCKVALCLASS hClass, uint32_t uSubClass, const char *pszNameFmt, ...) { AssertReturn(!(fFlags & ~RTSEMRW_FLAGS_NO_LOCK_VAL), VERR_INVALID_PARAMETER); /* * Allocate memory. */ int rc; struct RTSEMRWINTERNAL *pThis = (struct RTSEMRWINTERNAL *)RTMemAlloc(sizeof(struct RTSEMRWINTERNAL)); if (pThis) { /* * Create the semaphores. */ rc = RTSemEventCreateEx(&pThis->WriteEvent, RTSEMEVENT_FLAGS_NO_LOCK_VAL, NIL_RTLOCKVALCLASS, NULL); if (RT_SUCCESS(rc)) { rc = RTSemEventMultiCreateEx(&pThis->ReadEvent, RTSEMEVENT_FLAGS_NO_LOCK_VAL, NIL_RTLOCKVALCLASS, NULL); if (RT_SUCCESS(rc)) { rc = RTCritSectInitEx(&pThis->CritSect, RTCRITSECT_FLAGS_NO_LOCK_VAL, NIL_RTLOCKVALCLASS, RTLOCKVAL_SUB_CLASS_NONE, NULL); if (RT_SUCCESS(rc)) { /* * Signal the read semaphore and initialize other variables. */ rc = RTSemEventMultiSignal(pThis->ReadEvent); if (RT_SUCCESS(rc)) { pThis->u32Padding = UINT32_C(0xa5a55a5a); pThis->cReads = 0; pThis->cWrites = 0; pThis->cWriterReads = 0; pThis->cWritesWaiting = 0; pThis->hWriter = NIL_RTNATIVETHREAD; pThis->fNeedResetReadEvent = true; pThis->u32Magic = RTSEMRW_MAGIC; #ifdef RTSEMRW_STRICT bool const fLVEnabled = !(fFlags & RTSEMRW_FLAGS_NO_LOCK_VAL); if (!pszNameFmt) { static uint32_t volatile s_iSemRWAnon = 0; uint32_t i = ASMAtomicIncU32(&s_iSemRWAnon) - 1; RTLockValidatorRecExclInit(&pThis->ValidatorWrite, hClass, uSubClass, pThis, fLVEnabled, "RTSemRW-%u", i); RTLockValidatorRecSharedInit(&pThis->ValidatorRead, hClass, uSubClass, pThis, false /*fSignaller*/, fLVEnabled, "RTSemRW-%u", i); } else { va_list va; va_start(va, pszNameFmt); RTLockValidatorRecExclInitV(&pThis->ValidatorWrite, hClass, uSubClass, pThis, fLVEnabled, pszNameFmt, va); va_end(va); va_start(va, pszNameFmt); RTLockValidatorRecSharedInitV(&pThis->ValidatorRead, hClass, uSubClass, pThis, false /*fSignaller*/, fLVEnabled, pszNameFmt, va); va_end(va); } RTLockValidatorRecMakeSiblings(&pThis->ValidatorWrite.Core, &pThis->ValidatorRead.Core); #else RT_NOREF_PV(hClass); RT_NOREF_PV(uSubClass); RT_NOREF_PV(pszNameFmt); #endif *phRWSem = pThis; return VINF_SUCCESS; } RTCritSectDelete(&pThis->CritSect); } RTSemEventMultiDestroy(pThis->ReadEvent); } RTSemEventDestroy(pThis->WriteEvent); } RTMemFree(pThis); } else rc = VERR_NO_MEMORY; return rc; } RT_EXPORT_SYMBOL(RTSemRWCreate); RTDECL(int) RTSemRWDestroy(RTSEMRW hRWSem) { struct RTSEMRWINTERNAL *pThis = hRWSem; /* * Validate handle. */ if (pThis == NIL_RTSEMRW) return VINF_SUCCESS; AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, VERR_INVALID_HANDLE); /* * Check if busy. */ int rc = RTCritSectTryEnter(&pThis->CritSect); if (RT_SUCCESS(rc)) { if (!pThis->cReads && !pThis->cWrites) { /* * Make it invalid and unusable. */ ASMAtomicWriteU32(&pThis->u32Magic, ~RTSEMRW_MAGIC); pThis->cReads = UINT32_MAX; /* * Do actual cleanup. None of these can now fail. */ rc = RTSemEventMultiDestroy(pThis->ReadEvent); AssertMsgRC(rc, ("RTSemEventMultiDestroy failed! rc=%Rrc\n", rc)); pThis->ReadEvent = NIL_RTSEMEVENTMULTI; rc = RTSemEventDestroy(pThis->WriteEvent); AssertMsgRC(rc, ("RTSemEventDestroy failed! rc=%Rrc\n", rc)); pThis->WriteEvent = NIL_RTSEMEVENT; RTCritSectLeave(&pThis->CritSect); rc = RTCritSectDelete(&pThis->CritSect); AssertMsgRC(rc, ("RTCritSectDelete failed! rc=%Rrc\n", rc)); #ifdef RTSEMRW_STRICT RTLockValidatorRecSharedDelete(&pThis->ValidatorRead); RTLockValidatorRecExclDelete(&pThis->ValidatorWrite); #endif RTMemFree(pThis); rc = VINF_SUCCESS; } else { rc = VERR_SEM_BUSY; RTCritSectLeave(&pThis->CritSect); } } else { AssertMsgRC(rc, ("RTCritSectTryEnter failed! rc=%Rrc\n", rc)); rc = VERR_SEM_BUSY; } return rc; } RT_EXPORT_SYMBOL(RTSemRWDestroy); RTDECL(uint32_t) RTSemRWSetSubClass(RTSEMRW hRWSem, uint32_t uSubClass) { #ifdef RTSEMRW_STRICT /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, RTLOCKVAL_SUB_CLASS_INVALID); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, RTLOCKVAL_SUB_CLASS_INVALID); RTLockValidatorRecSharedSetSubClass(&pThis->ValidatorRead, uSubClass); return RTLockValidatorRecExclSetSubClass(&pThis->ValidatorWrite, uSubClass); #else RT_NOREF_PV(hRWSem); RT_NOREF_PV(uSubClass); return RTLOCKVAL_SUB_CLASS_INVALID; #endif } RT_EXPORT_SYMBOL(RTSemRWSetSubClass); DECL_FORCE_INLINE(int) rtSemRWRequestRead(RTSEMRW hRWSem, RTMSINTERVAL cMillies, bool fInterruptible, PCRTLOCKVALSRCPOS pSrcPos) { /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, VERR_INVALID_HANDLE); RTMSINTERVAL cMilliesInitial = cMillies; uint64_t tsStart = 0; if (cMillies != RT_INDEFINITE_WAIT && cMillies != 0) tsStart = RTTimeNanoTS(); #ifdef RTSEMRW_STRICT RTTHREAD hThreadSelf = RTThreadSelfAutoAdopt(); if (cMillies > 0) { int rc9; if (pThis->hWriter != NIL_RTTHREAD && pThis->hWriter == RTThreadNativeSelf()) rc9 = RTLockValidatorRecExclCheckOrder(&pThis->ValidatorWrite, hThreadSelf, pSrcPos, cMillies); else rc9 = RTLockValidatorRecSharedCheckOrder(&pThis->ValidatorRead, hThreadSelf, pSrcPos, cMillies); if (RT_FAILURE(rc9)) return rc9; } #endif /* * Take critsect. */ int rc = RTCritSectEnter(&pThis->CritSect); if (RT_FAILURE(rc)) { AssertMsgFailed(("RTCritSectEnter failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); return rc; } /* * Check if the state of affairs allows read access. * Do not block further readers if there is a writer waiting, as * that will break/deadlock reader recursion. */ if ( pThis->hWriter == NIL_RTNATIVETHREAD #if 0 && ( !pThis->cWritesWaiting || pThis->cReads) #endif ) { pThis->cReads++; Assert(pThis->cReads > 0); #ifdef RTSEMRW_STRICT RTLockValidatorRecSharedAddOwner(&pThis->ValidatorRead, hThreadSelf, pSrcPos); #endif RTCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } RTNATIVETHREAD hNativeSelf = pThis->CritSect.NativeThreadOwner; if (pThis->hWriter == hNativeSelf) { #ifdef RTSEMRW_STRICT int rc9 = RTLockValidatorRecExclRecursionMixed(&pThis->ValidatorWrite, &pThis->ValidatorRead.Core, pSrcPos); if (RT_FAILURE(rc9)) { RTCritSectLeave(&pThis->CritSect); return rc9; } #endif pThis->cWriterReads++; Assert(pThis->cWriterReads > 0); RTCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } RTCritSectLeave(&pThis->CritSect); /* * Wait till it's ready for reading. */ if (cMillies == 0) return VERR_TIMEOUT; #ifndef RTSEMRW_STRICT RTTHREAD hThreadSelf = RTThreadSelf(); #endif for (;;) { if (cMillies != RT_INDEFINITE_WAIT) { int64_t tsDelta = RTTimeNanoTS() - tsStart; if (tsDelta >= 1000000) { tsDelta /= 1000000; if ((uint64_t)tsDelta < cMilliesInitial) cMilliesInitial = (RTMSINTERVAL)tsDelta; else cMilliesInitial = 1; } } #ifdef RTSEMRW_STRICT rc = RTLockValidatorRecSharedCheckBlocking(&pThis->ValidatorRead, hThreadSelf, pSrcPos, true, cMillies, RTTHREADSTATE_RW_READ, false); if (RT_FAILURE(rc)) break; #else RTThreadBlocking(hThreadSelf, RTTHREADSTATE_RW_READ, false); RT_NOREF_PV(pSrcPos); #endif int rcWait; if (fInterruptible) rcWait = rc = RTSemEventMultiWaitNoResume(pThis->ReadEvent, cMillies); else rcWait = rc = RTSemEventMultiWait(pThis->ReadEvent, cMillies); RTThreadUnblocked(hThreadSelf, RTTHREADSTATE_RW_READ); if (RT_FAILURE(rc) && rc != VERR_TIMEOUT) /* handle timeout below */ { AssertMsgRC(rc, ("RTSemEventMultiWait failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); break; } if (pThis->u32Magic != RTSEMRW_MAGIC) { rc = VERR_SEM_DESTROYED; break; } /* * Re-take critsect and repeat the check we did before the loop. */ rc = RTCritSectEnter(&pThis->CritSect); if (RT_FAILURE(rc)) { AssertMsgFailed(("RTCritSectEnter failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); break; } if ( pThis->hWriter == NIL_RTNATIVETHREAD #if 0 && ( !pThis->cWritesWaiting || pThis->cReads) #endif ) { pThis->cReads++; Assert(pThis->cReads > 0); #ifdef RTSEMRW_STRICT RTLockValidatorRecSharedAddOwner(&pThis->ValidatorRead, hThreadSelf, pSrcPos); #endif RTCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } RTCritSectLeave(&pThis->CritSect); /* * Quit if the wait already timed out. */ if (rcWait == VERR_TIMEOUT) { rc = VERR_TIMEOUT; break; } } /* failed */ return rc; } RTDECL(int) RTSemRWRequestRead(RTSEMRW hRWSem, RTMSINTERVAL cMillies) { #ifndef RTSEMRW_STRICT return rtSemRWRequestRead(hRWSem, cMillies, false, NULL); #else RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_NORMAL_API(); return rtSemRWRequestRead(hRWSem, cMillies, false, &SrcPos); #endif } RT_EXPORT_SYMBOL(RTSemRWRequestRead); RTDECL(int) RTSemRWRequestReadDebug(RTSEMRW hRWSem, RTMSINTERVAL cMillies, RTHCUINTPTR uId, RT_SRC_POS_DECL) { RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_DEBUG_API(); return rtSemRWRequestRead(hRWSem, cMillies, false, &SrcPos); } RT_EXPORT_SYMBOL(RTSemRWRequestReadDebug); RTDECL(int) RTSemRWRequestReadNoResume(RTSEMRW hRWSem, RTMSINTERVAL cMillies) { #ifndef RTSEMRW_STRICT return rtSemRWRequestRead(hRWSem, cMillies, true, NULL); #else RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_NORMAL_API(); return rtSemRWRequestRead(hRWSem, cMillies, true, &SrcPos); #endif } RT_EXPORT_SYMBOL(RTSemRWRequestReadNoResume); RTDECL(int) RTSemRWRequestReadNoResumeDebug(RTSEMRW hRWSem, RTMSINTERVAL cMillies, RTHCUINTPTR uId, RT_SRC_POS_DECL) { RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_DEBUG_API(); return rtSemRWRequestRead(hRWSem, cMillies, true, &SrcPos); } RT_EXPORT_SYMBOL(RTSemRWRequestReadNoResumeDebug); RTDECL(int) RTSemRWReleaseRead(RTSEMRW hRWSem) { struct RTSEMRWINTERNAL *pThis = hRWSem; /* * Validate handle. */ AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, VERR_INVALID_HANDLE); /* * Take critsect. */ int rc = RTCritSectEnter(&pThis->CritSect); if (RT_SUCCESS(rc)) { if (pThis->hWriter == NIL_RTNATIVETHREAD) { #ifdef RTSEMRW_STRICT rc = RTLockValidatorRecSharedCheckAndRelease(&pThis->ValidatorRead, NIL_RTTHREAD); if (RT_SUCCESS(rc)) #endif { if (RT_LIKELY(pThis->cReads > 0)) { pThis->cReads--; /* Kick off a writer if appropriate. */ if ( pThis->cWritesWaiting > 0 && !pThis->cReads) { rc = RTSemEventSignal(pThis->WriteEvent); AssertMsgRC(rc, ("Failed to signal writers on rwsem %p, rc=%Rrc\n", hRWSem, rc)); } } else { AssertFailed(); rc = VERR_NOT_OWNER; } } } else { RTNATIVETHREAD hNativeSelf = pThis->CritSect.NativeThreadOwner; if (pThis->hWriter == hNativeSelf) { if (pThis->cWriterReads > 0) { #ifdef RTSEMRW_STRICT rc = RTLockValidatorRecExclUnwindMixed(&pThis->ValidatorWrite, &pThis->ValidatorRead.Core); if (RT_SUCCESS(rc)) #endif { pThis->cWriterReads--; } } else { AssertFailed(); rc = VERR_NOT_OWNER; } } else { AssertFailed(); rc = VERR_NOT_OWNER; } } RTCritSectLeave(&pThis->CritSect); } else AssertMsgFailed(("RTCritSectEnter failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); return rc; } RT_EXPORT_SYMBOL(RTSemRWReleaseRead); DECL_FORCE_INLINE(int) rtSemRWRequestWrite(RTSEMRW hRWSem, RTMSINTERVAL cMillies, bool fInterruptible, PCRTLOCKVALSRCPOS pSrcPos) { /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, VERR_INVALID_HANDLE); RTMSINTERVAL cMilliesInitial = cMillies; uint64_t tsStart = 0; if (cMillies != RT_INDEFINITE_WAIT && cMillies != 0) tsStart = RTTimeNanoTS(); #ifdef RTSEMRW_STRICT RTTHREAD hThreadSelf = NIL_RTTHREAD; if (cMillies) { hThreadSelf = RTThreadSelfAutoAdopt(); int rc9 = RTLockValidatorRecExclCheckOrder(&pThis->ValidatorWrite, hThreadSelf, pSrcPos, cMillies); if (RT_FAILURE(rc9)) return rc9; } #endif /* * Take critsect. */ int rc = RTCritSectEnter(&pThis->CritSect); if (RT_FAILURE(rc)) { AssertMsgFailed(("RTCritSectEnter failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); return rc; } /* * Check if the state of affairs allows write access. */ RTNATIVETHREAD hNativeSelf = pThis->CritSect.NativeThreadOwner; if ( !pThis->cReads && ( ( !pThis->cWrites && ( !pThis->cWritesWaiting /* play fair if we can wait */ || !cMillies) ) || pThis->hWriter == hNativeSelf ) ) { /* * Reset the reader event semaphore if necessary. */ if (pThis->fNeedResetReadEvent) { pThis->fNeedResetReadEvent = false; rc = RTSemEventMultiReset(pThis->ReadEvent); AssertMsgRC(rc, ("Failed to reset readers, rwsem %p, rc=%Rrc.\n", hRWSem, rc)); } pThis->cWrites++; pThis->hWriter = hNativeSelf; #ifdef RTSEMRW_STRICT RTLockValidatorRecExclSetOwner(&pThis->ValidatorWrite, hThreadSelf, pSrcPos, pThis->cWrites == 1); #endif RTCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } /* * Signal writer presence. */ if (cMillies != 0) pThis->cWritesWaiting++; RTCritSectLeave(&pThis->CritSect); /* * Wait till it's ready for writing. */ if (cMillies == 0) return VERR_TIMEOUT; #ifndef RTSEMRW_STRICT RTTHREAD hThreadSelf = RTThreadSelf(); #endif for (;;) { if (cMillies != RT_INDEFINITE_WAIT) { int64_t tsDelta = RTTimeNanoTS() - tsStart; if (tsDelta >= 1000000) { tsDelta /= 1000000; if ((uint64_t)tsDelta < cMilliesInitial) cMilliesInitial = (RTMSINTERVAL)tsDelta; else cMilliesInitial = 1; } } #ifdef RTSEMRW_STRICT rc = RTLockValidatorRecExclCheckBlocking(&pThis->ValidatorWrite, hThreadSelf, pSrcPos, true, cMillies, RTTHREADSTATE_RW_WRITE, false); if (RT_FAILURE(rc)) break; #else RTThreadBlocking(hThreadSelf, RTTHREADSTATE_RW_WRITE, false); RT_NOREF_PV(pSrcPos); #endif int rcWait; if (fInterruptible) rcWait = rc = RTSemEventWaitNoResume(pThis->WriteEvent, cMillies); else rcWait = rc = RTSemEventWait(pThis->WriteEvent, cMillies); RTThreadUnblocked(hThreadSelf, RTTHREADSTATE_RW_WRITE); if (RT_UNLIKELY(RT_FAILURE_NP(rc) && rc != VERR_TIMEOUT)) /* timeouts are handled below */ { AssertMsgRC(rc, ("RTSemEventWait failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); break; } if (RT_UNLIKELY(pThis->u32Magic != RTSEMRW_MAGIC)) { rc = VERR_SEM_DESTROYED; break; } /* * Re-take critsect and repeat the check we did prior to this loop. */ rc = RTCritSectEnter(&pThis->CritSect); if (RT_FAILURE(rc)) { AssertMsgFailed(("RTCritSectEnter failed on rwsem %p, rc=%Rrc\n", hRWSem, rc)); break; } if (!pThis->cReads && (!pThis->cWrites || pThis->hWriter == hNativeSelf)) { /* * Reset the reader event semaphore if necessary. */ if (pThis->fNeedResetReadEvent) { pThis->fNeedResetReadEvent = false; rc = RTSemEventMultiReset(pThis->ReadEvent); AssertMsgRC(rc, ("Failed to reset readers, rwsem %p, rc=%Rrc.\n", hRWSem, rc)); } pThis->cWrites++; pThis->hWriter = hNativeSelf; pThis->cWritesWaiting--; #ifdef RTSEMRW_STRICT RTLockValidatorRecExclSetOwner(&pThis->ValidatorWrite, hThreadSelf, pSrcPos, true); #endif RTCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } RTCritSectLeave(&pThis->CritSect); /* * Quit if the wait already timed out. */ if (rcWait == VERR_TIMEOUT) { rc = VERR_TIMEOUT; break; } } /* * Timeout/error case, clean up. */ if (pThis->u32Magic == RTSEMRW_MAGIC) { RTCritSectEnter(&pThis->CritSect); /* Adjust this counter, whether we got the critsect or not. */ pThis->cWritesWaiting--; RTCritSectLeave(&pThis->CritSect); } return rc; } RTDECL(int) RTSemRWRequestWrite(RTSEMRW hRWSem, RTMSINTERVAL cMillies) { #ifndef RTSEMRW_STRICT return rtSemRWRequestWrite(hRWSem, cMillies, false, NULL); #else RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_NORMAL_API(); return rtSemRWRequestWrite(hRWSem, cMillies, false, &SrcPos); #endif } RT_EXPORT_SYMBOL(RTSemRWRequestWrite); RTDECL(int) RTSemRWRequestWriteDebug(RTSEMRW hRWSem, RTMSINTERVAL cMillies, RTHCUINTPTR uId, RT_SRC_POS_DECL) { RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_DEBUG_API(); return rtSemRWRequestWrite(hRWSem, cMillies, false, &SrcPos); } RT_EXPORT_SYMBOL(RTSemRWRequestWriteDebug); RTDECL(int) RTSemRWRequestWriteNoResume(RTSEMRW hRWSem, RTMSINTERVAL cMillies) { #ifndef RTSEMRW_STRICT return rtSemRWRequestWrite(hRWSem, cMillies, true, NULL); #else RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_NORMAL_API(); return rtSemRWRequestWrite(hRWSem, cMillies, true, &SrcPos); #endif } RT_EXPORT_SYMBOL(RTSemRWRequestWriteNoResume); RTDECL(int) RTSemRWRequestWriteNoResumeDebug(RTSEMRW hRWSem, RTMSINTERVAL cMillies, RTHCUINTPTR uId, RT_SRC_POS_DECL) { RTLOCKVALSRCPOS SrcPos = RTLOCKVALSRCPOS_INIT_DEBUG_API(); return rtSemRWRequestWrite(hRWSem, cMillies, true, &SrcPos); } RT_EXPORT_SYMBOL(RTSemRWRequestWriteNoResumeDebug); RTDECL(int) RTSemRWReleaseWrite(RTSEMRW hRWSem) { /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, VERR_INVALID_HANDLE); /* * Take critsect. */ int rc = RTCritSectEnter(&pThis->CritSect); AssertRCReturn(rc, rc); /* * Check if owner. */ RTNATIVETHREAD hNativeSelf = pThis->CritSect.NativeThreadOwner; if (pThis->hWriter != hNativeSelf) { RTCritSectLeave(&pThis->CritSect); AssertMsgFailed(("Not read-write owner of rwsem %p.\n", hRWSem)); return VERR_NOT_OWNER; } #ifdef RTSEMRW_STRICT if (pThis->cWrites > 1 || !pThis->cWriterReads) /* don't check+release if VERR_WRONG_ORDER */ { int rc9 = RTLockValidatorRecExclReleaseOwner(&pThis->ValidatorWrite, pThis->cWrites == 1); if (RT_FAILURE(rc9)) { RTCritSectLeave(&pThis->CritSect); return rc9; } } #endif /* * Release ownership and remove ourselves from the writers count. */ Assert(pThis->cWrites > 0); pThis->cWrites--; if (!pThis->cWrites) { if (RT_UNLIKELY(pThis->cWriterReads > 0)) { pThis->cWrites++; RTCritSectLeave(&pThis->CritSect); AssertMsgFailed(("All recursive read locks need to be released prior to the final write lock! (%p)n\n", pThis)); return VERR_WRONG_ORDER; } pThis->hWriter = NIL_RTNATIVETHREAD; } /* * Release the readers if no more writers waiting, otherwise the writers. */ if (!pThis->cWritesWaiting) { rc = RTSemEventMultiSignal(pThis->ReadEvent); AssertMsgRC(rc, ("RTSemEventMultiSignal failed for rwsem %p, rc=%Rrc.\n", hRWSem, rc)); pThis->fNeedResetReadEvent = true; } else { rc = RTSemEventSignal(pThis->WriteEvent); AssertMsgRC(rc, ("Failed to signal writers on rwsem %p, rc=%Rrc\n", hRWSem, rc)); } RTCritSectLeave(&pThis->CritSect); return rc; } RT_EXPORT_SYMBOL(RTSemRWReleaseWrite); RTDECL(bool) RTSemRWIsWriteOwner(RTSEMRW hRWSem) { /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, false); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, false); /* * Check ownership. */ RTNATIVETHREAD hNativeSelf = RTThreadNativeSelf(); RTNATIVETHREAD hWriter; ASMAtomicUoReadHandle(&pThis->hWriter, &hWriter); return hWriter == hNativeSelf; } RT_EXPORT_SYMBOL(RTSemRWIsWriteOwner); RTDECL(bool) RTSemRWIsReadOwner(RTSEMRW hRWSem, bool fWannaHear) { /* * Validate handle. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, false); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, false); /* * Check write ownership. The writer is also a valid reader. */ RTNATIVETHREAD hNativeSelf = RTThreadNativeSelf(); RTNATIVETHREAD hWriter; ASMAtomicUoReadHandle(&pThis->hWriter, &hWriter); if (hWriter == hNativeSelf) return true; if (hWriter != NIL_RTNATIVETHREAD) return false; #ifdef RTSEMRW_STRICT /* * Ask the lock validator. */ NOREF(fWannaHear); return RTLockValidatorRecSharedIsOwner(&pThis->ValidatorRead, NIL_RTTHREAD); #else /* * If there are no reads we cannot be one of them... But if there are we * cannot know and can only return what the caller want to hear. */ if (pThis->cReads == 0) return false; return fWannaHear; #endif } RT_EXPORT_SYMBOL(RTSemRWIsReadOwner); RTDECL(uint32_t) RTSemRWGetWriteRecursion(RTSEMRW hRWSem) { struct RTSEMRWINTERNAL *pThis = hRWSem; /* * Validate handle. */ AssertPtrReturn(pThis, 0); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, 0); /* * Return the requested data. */ return pThis->cWrites; } RT_EXPORT_SYMBOL(RTSemRWGetWriteRecursion); RTDECL(uint32_t) RTSemRWGetWriterReadRecursion(RTSEMRW hRWSem) { struct RTSEMRWINTERNAL *pThis = hRWSem; /* * Validate handle. */ AssertPtrReturn(pThis, 0); AssertReturn(pThis->u32Magic == RTSEMRW_MAGIC, 0); /* * Return the requested data. */ return pThis->cWriterReads; } RT_EXPORT_SYMBOL(RTSemRWGetWriterReadRecursion); RTDECL(uint32_t) RTSemRWGetReadCount(RTSEMRW hRWSem) { /* * Validate input. */ struct RTSEMRWINTERNAL *pThis = hRWSem; AssertPtrReturn(pThis, 0); AssertMsgReturn(pThis->u32Magic == RTSEMRW_MAGIC, ("pThis=%p u32Magic=%#x\n", pThis, pThis->u32Magic), 0); /* * Return the requested data. */ return pThis->cReads; } RT_EXPORT_SYMBOL(RTSemRWGetReadCount);