/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "seccomon.h" /* This ifdef should match the one in sslsnce.c */ #if defined(XP_UNIX) || defined(XP_WIN32) || defined(XP_OS2) || defined(XP_BEOS) #include "sslmutex.h" #include "prerr.h" static SECStatus single_process_sslMutex_Init(sslMutex* pMutex) { PR_ASSERT(pMutex != 0 && pMutex->u.sslLock == 0); pMutex->u.sslLock = PR_NewLock(); if (!pMutex->u.sslLock) { return SECFailure; } return SECSuccess; } static SECStatus single_process_sslMutex_Destroy(sslMutex* pMutex) { PR_ASSERT(pMutex != 0); PR_ASSERT(pMutex->u.sslLock != 0); if (!pMutex->u.sslLock) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } PR_DestroyLock(pMutex->u.sslLock); return SECSuccess; } static SECStatus single_process_sslMutex_Unlock(sslMutex* pMutex) { PR_ASSERT(pMutex != 0); PR_ASSERT(pMutex->u.sslLock != 0); if (!pMutex->u.sslLock) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } PR_Unlock(pMutex->u.sslLock); return SECSuccess; } static SECStatus single_process_sslMutex_Lock(sslMutex* pMutex) { PR_ASSERT(pMutex != 0); PR_ASSERT(pMutex->u.sslLock != 0); if (!pMutex->u.sslLock) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } PR_Lock(pMutex->u.sslLock); return SECSuccess; } #if defined(LINUX) || defined(AIX) || defined(BEOS) || defined(BSDI) || \ (defined(NETBSD) && __NetBSD_Version__ < 500000000) || defined(OPENBSD) || defined(__GLIBC__) #include #include #include #include #include "unix_err.h" #include "pratom.h" #define SSL_MUTEX_MAGIC 0xfeedfd #define NONBLOCKING_POSTS 1 /* maybe this is faster */ #if NONBLOCKING_POSTS #ifndef FNONBLOCK #define FNONBLOCK O_NONBLOCK #endif static int setNonBlocking(int fd, int nonBlocking) { int flags; int err; flags = fcntl(fd, F_GETFL, 0); if (0 > flags) return flags; if (nonBlocking) flags |= FNONBLOCK; else flags &= ~FNONBLOCK; err = fcntl(fd, F_SETFL, flags); return err; } #endif SECStatus sslMutex_Init(sslMutex* pMutex, int shared) { int err; PR_ASSERT(pMutex); pMutex->isMultiProcess = (PRBool)(shared != 0); if (!shared) { return single_process_sslMutex_Init(pMutex); } pMutex->u.pipeStr.mPipes[0] = -1; pMutex->u.pipeStr.mPipes[1] = -1; pMutex->u.pipeStr.mPipes[2] = -1; pMutex->u.pipeStr.nWaiters = 0; err = pipe(pMutex->u.pipeStr.mPipes); if (err) { nss_MD_unix_map_default_error(errno); return err; } #if NONBLOCKING_POSTS err = setNonBlocking(pMutex->u.pipeStr.mPipes[1], 1); if (err) goto loser; #endif pMutex->u.pipeStr.mPipes[2] = SSL_MUTEX_MAGIC; #if defined(LINUX) && defined(i386) /* Pipe starts out empty */ return SECSuccess; #else /* Pipe starts with one byte. */ return sslMutex_Unlock(pMutex); #endif loser: nss_MD_unix_map_default_error(errno); close(pMutex->u.pipeStr.mPipes[0]); close(pMutex->u.pipeStr.mPipes[1]); return SECFailure; } SECStatus sslMutex_Destroy(sslMutex* pMutex, PRBool processLocal) { if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Destroy(pMutex); } if (pMutex->u.pipeStr.mPipes[2] != SSL_MUTEX_MAGIC) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } close(pMutex->u.pipeStr.mPipes[0]); close(pMutex->u.pipeStr.mPipes[1]); if (processLocal) { return SECSuccess; } pMutex->u.pipeStr.mPipes[0] = -1; pMutex->u.pipeStr.mPipes[1] = -1; pMutex->u.pipeStr.mPipes[2] = -1; pMutex->u.pipeStr.nWaiters = 0; return SECSuccess; } #if defined(LINUX) && defined(i386) /* No memory barrier needed for this platform */ /* nWaiters includes the holder of the lock (if any) and the number ** threads waiting for it. After incrementing nWaiters, if the count ** is exactly 1, then you have the lock and may proceed. If the ** count is greater than 1, then you must wait on the pipe. */ SECStatus sslMutex_Unlock(sslMutex* pMutex) { PRInt32 newValue; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Unlock(pMutex); } if (pMutex->u.pipeStr.mPipes[2] != SSL_MUTEX_MAGIC) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } /* Do Memory Barrier here. */ newValue = PR_ATOMIC_DECREMENT(&pMutex->u.pipeStr.nWaiters); if (newValue > 0) { int cc; char c = 1; do { cc = write(pMutex->u.pipeStr.mPipes[1], &c, 1); } while (cc < 0 && (errno == EINTR || errno == EAGAIN)); if (cc != 1) { if (cc < 0) nss_MD_unix_map_default_error(errno); else PORT_SetError(PR_UNKNOWN_ERROR); return SECFailure; } } return SECSuccess; } SECStatus sslMutex_Lock(sslMutex* pMutex) { PRInt32 newValue; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Lock(pMutex); } if (pMutex->u.pipeStr.mPipes[2] != SSL_MUTEX_MAGIC) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } newValue = PR_ATOMIC_INCREMENT(&pMutex->u.pipeStr.nWaiters); /* Do Memory Barrier here. */ if (newValue > 1) { int cc; char c; do { cc = read(pMutex->u.pipeStr.mPipes[0], &c, 1); } while (cc < 0 && errno == EINTR); if (cc != 1) { if (cc < 0) nss_MD_unix_map_default_error(errno); else PORT_SetError(PR_UNKNOWN_ERROR); return SECFailure; } } return SECSuccess; } #else /* Using Atomic operations requires the use of a memory barrier instruction ** on PowerPC, Sparc, and Alpha. NSPR's PR_Atomic functions do not perform ** them, and NSPR does not provide a function that does them (e.g. PR_Barrier). ** So, we don't use them on those platforms. */ SECStatus sslMutex_Unlock(sslMutex* pMutex) { int cc; char c = 1; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Unlock(pMutex); } if (pMutex->u.pipeStr.mPipes[2] != SSL_MUTEX_MAGIC) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } do { cc = write(pMutex->u.pipeStr.mPipes[1], &c, 1); } while (cc < 0 && (errno == EINTR || errno == EAGAIN)); if (cc != 1) { if (cc < 0) nss_MD_unix_map_default_error(errno); else PORT_SetError(PR_UNKNOWN_ERROR); return SECFailure; } return SECSuccess; } SECStatus sslMutex_Lock(sslMutex* pMutex) { int cc; char c; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Lock(pMutex); } if (pMutex->u.pipeStr.mPipes[2] != SSL_MUTEX_MAGIC) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } do { cc = read(pMutex->u.pipeStr.mPipes[0], &c, 1); } while (cc < 0 && errno == EINTR); if (cc != 1) { if (cc < 0) nss_MD_unix_map_default_error(errno); else PORT_SetError(PR_UNKNOWN_ERROR); return SECFailure; } return SECSuccess; } #endif #elif defined(WIN32) #include "win32err.h" /* on Windows, we need to find the optimal type of locking mechanism to use for the sslMutex. There are 3 cases : 1) single-process, use a PRLock, as for all other platforms 2) Win95 multi-process, use a Win32 mutex 3) on WINNT multi-process, use a PRLock + a Win32 mutex */ #ifdef WINNT SECStatus sslMutex_2LevelInit(sslMutex *sem) { /* the following adds a PRLock to sslMutex . This is done in each process of a multi-process server and is only needed on WINNT, if using fibers. We can't tell if native threads or fibers are used, so we always do it on WINNT */ PR_ASSERT(sem); if (sem) { /* we need to reset the sslLock in the children or the single_process init function below will assert */ sem->u.sslLock = NULL; } return single_process_sslMutex_Init(sem); } static SECStatus sslMutex_2LevelDestroy(sslMutex *sem) { return single_process_sslMutex_Destroy(sem); } #endif SECStatus sslMutex_Init(sslMutex *pMutex, int shared) { #ifdef WINNT SECStatus retvalue; #endif HANDLE hMutex; SECURITY_ATTRIBUTES attributes = { sizeof(SECURITY_ATTRIBUTES), NULL, TRUE }; PR_ASSERT(pMutex != 0 && (pMutex->u.sslMutx == 0 || pMutex->u.sslMutx == INVALID_HANDLE_VALUE)); pMutex->isMultiProcess = (PRBool)(shared != 0); if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Init(pMutex); } #ifdef WINNT /* we need a lock on WINNT for fibers in the parent process */ retvalue = sslMutex_2LevelInit(pMutex); if (SECSuccess != retvalue) return SECFailure; #endif if (!pMutex || ((hMutex = pMutex->u.sslMutx) != 0 && hMutex != INVALID_HANDLE_VALUE)) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } attributes.bInheritHandle = (shared ? TRUE : FALSE); hMutex = CreateMutex(&attributes, FALSE, NULL); if (hMutex == NULL) { hMutex = INVALID_HANDLE_VALUE; nss_MD_win32_map_default_error(GetLastError()); return SECFailure; } pMutex->u.sslMutx = hMutex; return SECSuccess; } SECStatus sslMutex_Destroy(sslMutex *pMutex, PRBool processLocal) { HANDLE hMutex; int rv; int retvalue = SECSuccess; PR_ASSERT(pMutex != 0); if (!pMutex) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Destroy(pMutex); } /* multi-process mode */ #ifdef WINNT /* on NT, get rid of the PRLock used for fibers within a process */ retvalue = sslMutex_2LevelDestroy(pMutex); #endif PR_ASSERT(pMutex->u.sslMutx != 0 && pMutex->u.sslMutx != INVALID_HANDLE_VALUE); if ((hMutex = pMutex->u.sslMutx) == 0 || hMutex == INVALID_HANDLE_VALUE) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } rv = CloseHandle(hMutex); /* ignore error */ if (!processLocal && rv) { pMutex->u.sslMutx = hMutex = INVALID_HANDLE_VALUE; } if (!rv) { nss_MD_win32_map_default_error(GetLastError()); retvalue = SECFailure; } return retvalue; } int sslMutex_Unlock(sslMutex *pMutex) { BOOL success = FALSE; HANDLE hMutex; PR_ASSERT(pMutex != 0); if (!pMutex) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Unlock(pMutex); } PR_ASSERT(pMutex->u.sslMutx != 0 && pMutex->u.sslMutx != INVALID_HANDLE_VALUE); if ((hMutex = pMutex->u.sslMutx) == 0 || hMutex == INVALID_HANDLE_VALUE) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } success = ReleaseMutex(hMutex); if (!success) { nss_MD_win32_map_default_error(GetLastError()); return SECFailure; } #ifdef WINNT return single_process_sslMutex_Unlock(pMutex); /* release PRLock for other fibers in the process */ #else return SECSuccess; #endif } int sslMutex_Lock(sslMutex *pMutex) { HANDLE hMutex; DWORD event; DWORD lastError; SECStatus rv; SECStatus retvalue = SECSuccess; PR_ASSERT(pMutex != 0); if (!pMutex) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; } if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Lock(pMutex); } #ifdef WINNT /* lock first to preserve from other threads/fibers in the same process */ retvalue = single_process_sslMutex_Lock(pMutex); #endif PR_ASSERT(pMutex->u.sslMutx != 0 && pMutex->u.sslMutx != INVALID_HANDLE_VALUE); if ((hMutex = pMutex->u.sslMutx) == 0 || hMutex == INVALID_HANDLE_VALUE) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return SECFailure; /* what else ? */ } /* acquire the mutex to be the only owner accross all other processes */ event = WaitForSingleObject(hMutex, INFINITE); switch (event) { case WAIT_OBJECT_0: case WAIT_ABANDONED: rv = SECSuccess; break; case WAIT_TIMEOUT: #if defined(WAIT_IO_COMPLETION) case WAIT_IO_COMPLETION: #endif default: /* should never happen. nothing we can do. */ PR_ASSERT(!("WaitForSingleObject returned invalid value.")); PORT_SetError(PR_UNKNOWN_ERROR); rv = SECFailure; break; case WAIT_FAILED: /* failure returns this */ rv = SECFailure; lastError = GetLastError(); /* for debugging */ nss_MD_win32_map_default_error(lastError); break; } if (!(SECSuccess == retvalue && SECSuccess == rv)) { return SECFailure; } return SECSuccess; } #elif defined(XP_UNIX) && !defined(DARWIN) #include #include "unix_err.h" SECStatus sslMutex_Init(sslMutex* pMutex, int shared) { int rv; PR_ASSERT(pMutex); pMutex->isMultiProcess = (PRBool)(shared != 0); if (!shared) { return single_process_sslMutex_Init(pMutex); } do { rv = sem_init(&pMutex->u.sem, shared, 1); } while (rv < 0 && errno == EINTR); if (rv < 0) { nss_MD_unix_map_default_error(errno); return SECFailure; } return SECSuccess; } SECStatus sslMutex_Destroy(sslMutex* pMutex, PRBool processLocal) { int rv; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Destroy(pMutex); } /* semaphores are global resources. See SEM_DESTROY(3) man page */ if (processLocal) { return SECSuccess; } do { rv = sem_destroy(&pMutex->u.sem); } while (rv < 0 && errno == EINTR); if (rv < 0) { nss_MD_unix_map_default_error(errno); return SECFailure; } return SECSuccess; } SECStatus sslMutex_Unlock(sslMutex* pMutex) { int rv; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Unlock(pMutex); } do { rv = sem_post(&pMutex->u.sem); } while (rv < 0 && errno == EINTR); if (rv < 0) { nss_MD_unix_map_default_error(errno); return SECFailure; } return SECSuccess; } SECStatus sslMutex_Lock(sslMutex* pMutex) { int rv; if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Lock(pMutex); } do { rv = sem_wait(&pMutex->u.sem); } while (rv < 0 && errno == EINTR); if (rv < 0) { nss_MD_unix_map_default_error(errno); return SECFailure; } return SECSuccess; } #else SECStatus sslMutex_Init(sslMutex* pMutex, int shared) { PR_ASSERT(pMutex); pMutex->isMultiProcess = (PRBool)(shared != 0); if (!shared) { return single_process_sslMutex_Init(pMutex); } PORT_Assert(!("sslMutex_Init not implemented for multi-process applications !")); PORT_SetError(PR_NOT_IMPLEMENTED_ERROR); return SECFailure; } SECStatus sslMutex_Destroy(sslMutex* pMutex, PRBool processLocal) { PR_ASSERT(pMutex); if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Destroy(pMutex); } PORT_Assert(!("sslMutex_Destroy not implemented for multi-process applications !")); PORT_SetError(PR_NOT_IMPLEMENTED_ERROR); return SECFailure; } SECStatus sslMutex_Unlock(sslMutex* pMutex) { PR_ASSERT(pMutex); if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Unlock(pMutex); } PORT_Assert(!("sslMutex_Unlock not implemented for multi-process applications !")); PORT_SetError(PR_NOT_IMPLEMENTED_ERROR); return SECFailure; } SECStatus sslMutex_Lock(sslMutex* pMutex) { PR_ASSERT(pMutex); if (PR_FALSE == pMutex->isMultiProcess) { return single_process_sslMutex_Lock(pMutex); } PORT_Assert(!("sslMutex_Lock not implemented for multi-process applications !")); PORT_SetError(PR_NOT_IMPLEMENTED_ERROR); return SECFailure; } #endif #endif