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author | Matt A. Tobin <mattatobin@localhost.localdomain> | 2018-02-02 04:16:08 -0500 |
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committer | Matt A. Tobin <mattatobin@localhost.localdomain> | 2018-02-02 04:16:08 -0500 |
commit | 5f8de423f190bbb79a62f804151bc24824fa32d8 (patch) | |
tree | 10027f336435511475e392454359edea8e25895d /nsprpub/pr/src/md/unix/unix.c | |
parent | 49ee0794b5d912db1f95dce6eb52d781dc210db5 (diff) | |
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Add m-esr52 at 52.6.0
Diffstat (limited to 'nsprpub/pr/src/md/unix/unix.c')
-rw-r--r-- | nsprpub/pr/src/md/unix/unix.c | 3787 |
1 files changed, 3787 insertions, 0 deletions
diff --git a/nsprpub/pr/src/md/unix/unix.c b/nsprpub/pr/src/md/unix/unix.c new file mode 100644 index 000000000..fdae1199c --- /dev/null +++ b/nsprpub/pr/src/md/unix/unix.c @@ -0,0 +1,3787 @@ +/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ +/* 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 "primpl.h" + +#include <string.h> +#include <signal.h> +#include <unistd.h> +#include <fcntl.h> +#include <sys/types.h> +#include <sys/socket.h> +#include <sys/time.h> +#include <sys/ioctl.h> +#include <sys/mman.h> +#include <unistd.h> +#include <sys/utsname.h> + +#ifdef _PR_POLL_AVAILABLE +#include <poll.h> +#endif + +#if defined(ANDROID) +#include <android/api-level.h> +#endif + +/* To get FIONREAD */ +#if defined(UNIXWARE) +#include <sys/filio.h> +#endif + +#if defined(NTO) +#include <sys/statvfs.h> +#endif + +/* + * Make sure _PRSockLen_t is 32-bit, because we will cast a PRUint32* or + * PRInt32* pointer to a _PRSockLen_t* pointer. + */ +#if defined(HAVE_SOCKLEN_T) \ + || (defined(__GLIBC__) && __GLIBC__ >= 2) +#define _PRSockLen_t socklen_t +#elif defined(IRIX) || defined(HPUX) || defined(OSF1) || defined(SOLARIS) \ + || defined(AIX4_1) || defined(LINUX) \ + || defined(BSDI) || defined(SCO) \ + || defined(DARWIN) \ + || defined(QNX) +#define _PRSockLen_t int +#elif (defined(AIX) && !defined(AIX4_1)) || defined(FREEBSD) \ + || defined(NETBSD) || defined(OPENBSD) || defined(UNIXWARE) \ + || defined(DGUX) || defined(NTO) || defined(RISCOS) +#define _PRSockLen_t size_t +#else +#error "Cannot determine architecture" +#endif + +/* +** Global lock variable used to bracket calls into rusty libraries that +** aren't thread safe (like libc, libX, etc). +*/ +static PRLock *_pr_rename_lock = NULL; +static PRMonitor *_pr_Xfe_mon = NULL; + +static PRInt64 minus_one; + +sigset_t timer_set; + +#if !defined(_PR_PTHREADS) + +static sigset_t empty_set; + +#ifdef SOLARIS +#include <sys/file.h> +#include <sys/filio.h> +#endif + +#ifndef PIPE_BUF +#define PIPE_BUF 512 +#endif + +/* + * _nspr_noclock - if set clock interrupts are disabled + */ +int _nspr_noclock = 1; + +#ifdef IRIX +extern PRInt32 _nspr_terminate_on_error; +#endif + +/* + * There is an assertion in this code that NSPR's definition of PRIOVec + * is bit compatible with UNIX' definition of a struct iovec. This is + * applicable to the 'writev()' operations where the types are casually + * cast to avoid warnings. + */ + +int _pr_md_pipefd[2] = { -1, -1 }; +static char _pr_md_pipebuf[PIPE_BUF]; +static PRInt32 local_io_wait(PRInt32 osfd, PRInt32 wait_flag, + PRIntervalTime timeout); + +_PRInterruptTable _pr_interruptTable[] = { + { + "clock", _PR_MISSED_CLOCK, _PR_ClockInterrupt, }, + { + 0 } +}; + +void _MD_unix_init_running_cpu(_PRCPU *cpu) +{ + PR_INIT_CLIST(&(cpu->md.md_unix.ioQ)); + cpu->md.md_unix.ioq_max_osfd = -1; + cpu->md.md_unix.ioq_timeout = PR_INTERVAL_NO_TIMEOUT; +} + +PRStatus _MD_open_dir(_MDDir *d, const char *name) +{ +int err; + + d->d = opendir(name); + if (!d->d) { + err = _MD_ERRNO(); + _PR_MD_MAP_OPENDIR_ERROR(err); + return PR_FAILURE; + } + return PR_SUCCESS; +} + +PRInt32 _MD_close_dir(_MDDir *d) +{ +int rv = 0, err; + + if (d->d) { + rv = closedir(d->d); + if (rv == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_CLOSEDIR_ERROR(err); + } + } + return rv; +} + +char * _MD_read_dir(_MDDir *d, PRIntn flags) +{ +struct dirent *de; +int err; + + for (;;) { + /* + * XXX: readdir() is not MT-safe. There is an MT-safe version + * readdir_r() on some systems. + */ + _MD_ERRNO() = 0; + de = readdir(d->d); + if (!de) { + err = _MD_ERRNO(); + _PR_MD_MAP_READDIR_ERROR(err); + return 0; + } + if ((flags & PR_SKIP_DOT) && + (de->d_name[0] == '.') && (de->d_name[1] == 0)) + continue; + if ((flags & PR_SKIP_DOT_DOT) && + (de->d_name[0] == '.') && (de->d_name[1] == '.') && + (de->d_name[2] == 0)) + continue; + if ((flags & PR_SKIP_HIDDEN) && (de->d_name[0] == '.')) + continue; + break; + } + return de->d_name; +} + +PRInt32 _MD_delete(const char *name) +{ +PRInt32 rv, err; +#ifdef UNIXWARE + sigset_t set, oset; +#endif + +#ifdef UNIXWARE + sigfillset(&set); + sigprocmask(SIG_SETMASK, &set, &oset); +#endif + rv = unlink(name); +#ifdef UNIXWARE + sigprocmask(SIG_SETMASK, &oset, NULL); +#endif + if (rv == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_UNLINK_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_rename(const char *from, const char *to) +{ + PRInt32 rv = -1, err; + + /* + ** This is trying to enforce the semantics of WINDOZE' rename + ** operation. That means one is not allowed to rename over top + ** of an existing file. Holding a lock across these two function + ** and the open function is known to be a bad idea, but .... + */ + if (NULL != _pr_rename_lock) + PR_Lock(_pr_rename_lock); + if (0 == access(to, F_OK)) + PR_SetError(PR_FILE_EXISTS_ERROR, 0); + else + { + rv = rename(from, to); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_RENAME_ERROR(err); + } + } + if (NULL != _pr_rename_lock) + PR_Unlock(_pr_rename_lock); + return rv; +} + +PRInt32 _MD_access(const char *name, PRAccessHow how) +{ +PRInt32 rv, err; +int amode; + + switch (how) { + case PR_ACCESS_WRITE_OK: + amode = W_OK; + break; + case PR_ACCESS_READ_OK: + amode = R_OK; + break; + case PR_ACCESS_EXISTS: + amode = F_OK; + break; + default: + PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); + rv = -1; + goto done; + } + rv = access(name, amode); + + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_ACCESS_ERROR(err); + } + +done: + return(rv); +} + +PRInt32 _MD_mkdir(const char *name, PRIntn mode) +{ +int rv, err; + + /* + ** This lock is used to enforce rename semantics as described + ** in PR_Rename. Look there for more fun details. + */ + if (NULL !=_pr_rename_lock) + PR_Lock(_pr_rename_lock); + rv = mkdir(name, mode); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_MKDIR_ERROR(err); + } + if (NULL !=_pr_rename_lock) + PR_Unlock(_pr_rename_lock); + return rv; +} + +PRInt32 _MD_rmdir(const char *name) +{ +int rv, err; + + rv = rmdir(name); + if (rv == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_RMDIR_ERROR(err); + } + return rv; +} + +PRInt32 _MD_read(PRFileDesc *fd, void *buf, PRInt32 amount) +{ +PRThread *me = _PR_MD_CURRENT_THREAD(); +PRInt32 rv, err; +#ifndef _PR_USE_POLL +fd_set rd; +#else +struct pollfd pfd; +#endif /* _PR_USE_POLL */ +PRInt32 osfd = fd->secret->md.osfd; + +#ifndef _PR_USE_POLL + FD_ZERO(&rd); + FD_SET(osfd, &rd); +#else + pfd.fd = osfd; + pfd.events = POLLIN; +#endif /* _PR_USE_POLL */ + while ((rv = read(osfd,buf,amount)) == -1) { + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_READ, + PR_INTERVAL_NO_TIMEOUT)) < 0) + goto done; + } else { +#ifndef _PR_USE_POLL + while ((rv = _MD_SELECT(osfd + 1, &rd, NULL, NULL, NULL)) + == -1 && (err = _MD_ERRNO()) == EINTR) { + /* retry _MD_SELECT() if it is interrupted */ + } +#else /* _PR_USE_POLL */ + while ((rv = _MD_POLL(&pfd, 1, -1)) + == -1 && (err = _MD_ERRNO()) == EINTR) { + /* retry _MD_POLL() if it is interrupted */ + } +#endif /* _PR_USE_POLL */ + if (rv == -1) { + break; + } + } + if (_PR_PENDING_INTERRUPT(me)) + break; + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + } else { + _PR_MD_MAP_READ_ERROR(err); + } + } +done: + return(rv); +} + +PRInt32 _MD_write(PRFileDesc *fd, const void *buf, PRInt32 amount) +{ +PRThread *me = _PR_MD_CURRENT_THREAD(); +PRInt32 rv, err; +#ifndef _PR_USE_POLL +fd_set wd; +#else +struct pollfd pfd; +#endif /* _PR_USE_POLL */ +PRInt32 osfd = fd->secret->md.osfd; + +#ifndef _PR_USE_POLL + FD_ZERO(&wd); + FD_SET(osfd, &wd); +#else + pfd.fd = osfd; + pfd.events = POLLOUT; +#endif /* _PR_USE_POLL */ + while ((rv = write(osfd,buf,amount)) == -1) { + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_WRITE, + PR_INTERVAL_NO_TIMEOUT)) < 0) + goto done; + } else { +#ifndef _PR_USE_POLL + while ((rv = _MD_SELECT(osfd + 1, NULL, &wd, NULL, NULL)) + == -1 && (err = _MD_ERRNO()) == EINTR) { + /* retry _MD_SELECT() if it is interrupted */ + } +#else /* _PR_USE_POLL */ + while ((rv = _MD_POLL(&pfd, 1, -1)) + == -1 && (err = _MD_ERRNO()) == EINTR) { + /* retry _MD_POLL() if it is interrupted */ + } +#endif /* _PR_USE_POLL */ + if (rv == -1) { + break; + } + } + if (_PR_PENDING_INTERRUPT(me)) + break; + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + } else { + _PR_MD_MAP_WRITE_ERROR(err); + } + } +done: + return(rv); +} + +PRInt32 _MD_fsync(PRFileDesc *fd) +{ +PRInt32 rv, err; + + rv = fsync(fd->secret->md.osfd); + if (rv == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_FSYNC_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_close(PRInt32 osfd) +{ +PRInt32 rv, err; + + rv = close(osfd); + if (rv == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_CLOSE_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_socket(PRInt32 domain, PRInt32 type, PRInt32 proto) +{ + PRInt32 osfd, err; + + osfd = socket(domain, type, proto); + + if (osfd == -1) { + err = _MD_ERRNO(); + _PR_MD_MAP_SOCKET_ERROR(err); + return(osfd); + } + + return(osfd); +} + +PRInt32 _MD_socketavailable(PRFileDesc *fd) +{ + PRInt32 result; + + if (ioctl(fd->secret->md.osfd, FIONREAD, &result) < 0) { + _PR_MD_MAP_SOCKETAVAILABLE_ERROR(_MD_ERRNO()); + return -1; + } + return result; +} + +PRInt64 _MD_socketavailable64(PRFileDesc *fd) +{ + PRInt64 result; + LL_I2L(result, _MD_socketavailable(fd)); + return result; +} /* _MD_socketavailable64 */ + +#define READ_FD 1 +#define WRITE_FD 2 + +/* + * socket_io_wait -- + * + * wait for socket i/o, periodically checking for interrupt + * + * The first implementation uses select(), for platforms without + * poll(). The second (preferred) implementation uses poll(). + */ + +#ifndef _PR_USE_POLL + +static PRInt32 socket_io_wait(PRInt32 osfd, PRInt32 fd_type, + PRIntervalTime timeout) +{ + PRInt32 rv = -1; + struct timeval tv; + PRThread *me = _PR_MD_CURRENT_THREAD(); + PRIntervalTime epoch, now, elapsed, remaining; + PRBool wait_for_remaining; + PRInt32 syserror; + fd_set rd_wr; + + switch (timeout) { + case PR_INTERVAL_NO_WAIT: + PR_SetError(PR_IO_TIMEOUT_ERROR, 0); + break; + case PR_INTERVAL_NO_TIMEOUT: + /* + * This is a special case of the 'default' case below. + * Please see the comments there. + */ + tv.tv_sec = _PR_INTERRUPT_CHECK_INTERVAL_SECS; + tv.tv_usec = 0; + FD_ZERO(&rd_wr); + do { + FD_SET(osfd, &rd_wr); + if (fd_type == READ_FD) + rv = _MD_SELECT(osfd + 1, &rd_wr, NULL, NULL, &tv); + else + rv = _MD_SELECT(osfd + 1, NULL, &rd_wr, NULL, &tv); + if (rv == -1 && (syserror = _MD_ERRNO()) != EINTR) { + _PR_MD_MAP_SELECT_ERROR(syserror); + break; + } + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + rv = -1; + break; + } + } while (rv == 0 || (rv == -1 && syserror == EINTR)); + break; + default: + now = epoch = PR_IntervalNow(); + remaining = timeout; + FD_ZERO(&rd_wr); + do { + /* + * We block in _MD_SELECT for at most + * _PR_INTERRUPT_CHECK_INTERVAL_SECS seconds, + * so that there is an upper limit on the delay + * before the interrupt bit is checked. + */ + wait_for_remaining = PR_TRUE; + tv.tv_sec = PR_IntervalToSeconds(remaining); + if (tv.tv_sec > _PR_INTERRUPT_CHECK_INTERVAL_SECS) { + wait_for_remaining = PR_FALSE; + tv.tv_sec = _PR_INTERRUPT_CHECK_INTERVAL_SECS; + tv.tv_usec = 0; + } else { + tv.tv_usec = PR_IntervalToMicroseconds( + remaining - + PR_SecondsToInterval(tv.tv_sec)); + } + FD_SET(osfd, &rd_wr); + if (fd_type == READ_FD) + rv = _MD_SELECT(osfd + 1, &rd_wr, NULL, NULL, &tv); + else + rv = _MD_SELECT(osfd + 1, NULL, &rd_wr, NULL, &tv); + /* + * we don't consider EINTR a real error + */ + if (rv == -1 && (syserror = _MD_ERRNO()) != EINTR) { + _PR_MD_MAP_SELECT_ERROR(syserror); + break; + } + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + rv = -1; + break; + } + /* + * We loop again if _MD_SELECT timed out or got interrupted + * by a signal, and the timeout deadline has not passed yet. + */ + if (rv == 0 || (rv == -1 && syserror == EINTR)) { + /* + * If _MD_SELECT timed out, we know how much time + * we spent in blocking, so we can avoid a + * PR_IntervalNow() call. + */ + if (rv == 0) { + if (wait_for_remaining) { + now += remaining; + } else { + now += PR_SecondsToInterval(tv.tv_sec) + + PR_MicrosecondsToInterval(tv.tv_usec); + } + } else { + now = PR_IntervalNow(); + } + elapsed = (PRIntervalTime) (now - epoch); + if (elapsed >= timeout) { + PR_SetError(PR_IO_TIMEOUT_ERROR, 0); + rv = -1; + break; + } else { + remaining = timeout - elapsed; + } + } + } while (rv == 0 || (rv == -1 && syserror == EINTR)); + break; + } + return(rv); +} + +#else /* _PR_USE_POLL */ + +static PRInt32 socket_io_wait(PRInt32 osfd, PRInt32 fd_type, + PRIntervalTime timeout) +{ + PRInt32 rv = -1; + int msecs; + PRThread *me = _PR_MD_CURRENT_THREAD(); + PRIntervalTime epoch, now, elapsed, remaining; + PRBool wait_for_remaining; + PRInt32 syserror; + struct pollfd pfd; + + switch (timeout) { + case PR_INTERVAL_NO_WAIT: + PR_SetError(PR_IO_TIMEOUT_ERROR, 0); + break; + case PR_INTERVAL_NO_TIMEOUT: + /* + * This is a special case of the 'default' case below. + * Please see the comments there. + */ + msecs = _PR_INTERRUPT_CHECK_INTERVAL_SECS * 1000; + pfd.fd = osfd; + if (fd_type == READ_FD) { + pfd.events = POLLIN; + } else { + pfd.events = POLLOUT; + } + do { + rv = _MD_POLL(&pfd, 1, msecs); + if (rv == -1 && (syserror = _MD_ERRNO()) != EINTR) { + _PR_MD_MAP_POLL_ERROR(syserror); + break; + } + /* + * If POLLERR is set, don't process it; retry the operation + */ + if ((rv == 1) && (pfd.revents & (POLLHUP | POLLNVAL))) { + rv = -1; + _PR_MD_MAP_POLL_REVENTS_ERROR(pfd.revents); + break; + } + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + rv = -1; + break; + } + } while (rv == 0 || (rv == -1 && syserror == EINTR)); + break; + default: + now = epoch = PR_IntervalNow(); + remaining = timeout; + pfd.fd = osfd; + if (fd_type == READ_FD) { + pfd.events = POLLIN; + } else { + pfd.events = POLLOUT; + } + do { + /* + * We block in _MD_POLL for at most + * _PR_INTERRUPT_CHECK_INTERVAL_SECS seconds, + * so that there is an upper limit on the delay + * before the interrupt bit is checked. + */ + wait_for_remaining = PR_TRUE; + msecs = PR_IntervalToMilliseconds(remaining); + if (msecs > _PR_INTERRUPT_CHECK_INTERVAL_SECS * 1000) { + wait_for_remaining = PR_FALSE; + msecs = _PR_INTERRUPT_CHECK_INTERVAL_SECS * 1000; + } + rv = _MD_POLL(&pfd, 1, msecs); + /* + * we don't consider EINTR a real error + */ + if (rv == -1 && (syserror = _MD_ERRNO()) != EINTR) { + _PR_MD_MAP_POLL_ERROR(syserror); + break; + } + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + rv = -1; + break; + } + /* + * If POLLERR is set, don't process it; retry the operation + */ + if ((rv == 1) && (pfd.revents & (POLLHUP | POLLNVAL))) { + rv = -1; + _PR_MD_MAP_POLL_REVENTS_ERROR(pfd.revents); + break; + } + /* + * We loop again if _MD_POLL timed out or got interrupted + * by a signal, and the timeout deadline has not passed yet. + */ + if (rv == 0 || (rv == -1 && syserror == EINTR)) { + /* + * If _MD_POLL timed out, we know how much time + * we spent in blocking, so we can avoid a + * PR_IntervalNow() call. + */ + if (rv == 0) { + if (wait_for_remaining) { + now += remaining; + } else { + now += PR_MillisecondsToInterval(msecs); + } + } else { + now = PR_IntervalNow(); + } + elapsed = (PRIntervalTime) (now - epoch); + if (elapsed >= timeout) { + PR_SetError(PR_IO_TIMEOUT_ERROR, 0); + rv = -1; + break; + } else { + remaining = timeout - elapsed; + } + } + } while (rv == 0 || (rv == -1 && syserror == EINTR)); + break; + } + return(rv); +} + +#endif /* _PR_USE_POLL */ + +static PRInt32 local_io_wait( + PRInt32 osfd, + PRInt32 wait_flag, + PRIntervalTime timeout) +{ + _PRUnixPollDesc pd; + PRInt32 rv; + + PR_LOG(_pr_io_lm, PR_LOG_MIN, + ("waiting to %s on osfd=%d", + (wait_flag == _PR_UNIX_POLL_READ) ? "read" : "write", + osfd)); + + if (timeout == PR_INTERVAL_NO_WAIT) return 0; + + pd.osfd = osfd; + pd.in_flags = wait_flag; + pd.out_flags = 0; + + rv = _PR_WaitForMultipleFDs(&pd, 1, timeout); + + if (rv == 0) { + PR_SetError(PR_IO_TIMEOUT_ERROR, 0); + rv = -1; + } + return rv; +} + + +PRInt32 _MD_recv(PRFileDesc *fd, void *buf, PRInt32 amount, + PRInt32 flags, PRIntervalTime timeout) +{ + PRInt32 osfd = fd->secret->md.osfd; + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); + +/* + * Many OS's (Solaris, Unixware) have a broken recv which won't read + * from socketpairs. As long as we don't use flags on socketpairs, this + * is a decent fix. - mikep + */ +#if defined(UNIXWARE) || defined(SOLARIS) + while ((rv = read(osfd,buf,amount)) == -1) { +#else + while ((rv = recv(osfd,buf,amount,flags)) == -1) { +#endif + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd,_PR_UNIX_POLL_READ,timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, READ_FD, timeout)) < 0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + _PR_MD_MAP_RECV_ERROR(err); + } +done: + return(rv); +} + +PRInt32 _MD_recvfrom(PRFileDesc *fd, void *buf, PRInt32 amount, + PRIntn flags, PRNetAddr *addr, PRUint32 *addrlen, + PRIntervalTime timeout) +{ + PRInt32 osfd = fd->secret->md.osfd; + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); + + while ((*addrlen = PR_NETADDR_SIZE(addr)), + ((rv = recvfrom(osfd, buf, amount, flags, + (struct sockaddr *) addr, (_PRSockLen_t *)addrlen)) == -1)) { + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_READ, timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, READ_FD, timeout)) < 0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + _PR_MD_MAP_RECVFROM_ERROR(err); + } +done: +#ifdef _PR_HAVE_SOCKADDR_LEN + if (rv != -1) { + /* ignore the sa_len field of struct sockaddr */ + if (addr) { + addr->raw.family = ((struct sockaddr *) addr)->sa_family; + } + } +#endif /* _PR_HAVE_SOCKADDR_LEN */ + return(rv); +} + +PRInt32 _MD_send(PRFileDesc *fd, const void *buf, PRInt32 amount, + PRInt32 flags, PRIntervalTime timeout) +{ + PRInt32 osfd = fd->secret->md.osfd; + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); +#if defined(SOLARIS) + PRInt32 tmp_amount = amount; +#endif + + /* + * On pre-2.6 Solaris, send() is much slower than write(). + * On 2.6 and beyond, with in-kernel sockets, send() and + * write() are fairly equivalent in performance. + */ +#if defined(SOLARIS) + PR_ASSERT(0 == flags); + while ((rv = write(osfd,buf,tmp_amount)) == -1) { +#else + while ((rv = send(osfd,buf,amount,flags)) == -1) { +#endif + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, WRITE_FD, timeout))< 0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { +#if defined(SOLARIS) + /* + * The write system call has been reported to return the ERANGE + * error on occasion. Try to write in smaller chunks to workaround + * this bug. + */ + if (err == ERANGE) { + if (tmp_amount > 1) { + tmp_amount = tmp_amount/2; /* half the bytes */ + continue; + } + } +#endif + break; + } + } + /* + * optimization; if bytes sent is less than "amount" call + * select before returning. This is because it is likely that + * the next send() call will return EWOULDBLOCK. + */ + if ((!fd->secret->nonblocking) && (rv > 0) && (rv < amount) + && (timeout != PR_INTERVAL_NO_WAIT)) { + if (_PR_IS_NATIVE_THREAD(me)) { + if (socket_io_wait(osfd, WRITE_FD, timeout)< 0) { + rv = -1; + goto done; + } + } else { + if (local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout) < 0) { + rv = -1; + goto done; + } + } + } + if (rv < 0) { + _PR_MD_MAP_SEND_ERROR(err); + } +done: + return(rv); +} + +PRInt32 _MD_sendto( + PRFileDesc *fd, const void *buf, PRInt32 amount, PRIntn flags, + const PRNetAddr *addr, PRUint32 addrlen, PRIntervalTime timeout) +{ + PRInt32 osfd = fd->secret->md.osfd; + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); +#ifdef _PR_HAVE_SOCKADDR_LEN + PRNetAddr addrCopy; + + addrCopy = *addr; + ((struct sockaddr *) &addrCopy)->sa_len = addrlen; + ((struct sockaddr *) &addrCopy)->sa_family = addr->raw.family; + + while ((rv = sendto(osfd, buf, amount, flags, + (struct sockaddr *) &addrCopy, addrlen)) == -1) { +#else + while ((rv = sendto(osfd, buf, amount, flags, + (struct sockaddr *) addr, addrlen)) == -1) { +#endif + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, WRITE_FD, timeout))< 0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + _PR_MD_MAP_SENDTO_ERROR(err); + } +done: + return(rv); +} + +PRInt32 _MD_writev( + PRFileDesc *fd, const PRIOVec *iov, + PRInt32 iov_size, PRIntervalTime timeout) +{ + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); + PRInt32 index, amount = 0; + PRInt32 osfd = fd->secret->md.osfd; + + /* + * Calculate the total number of bytes to be sent; needed for + * optimization later. + * We could avoid this if this number was passed in; but it is + * probably not a big deal because iov_size is usually small (less than + * 3) + */ + if (!fd->secret->nonblocking) { + for (index=0; index<iov_size; index++) { + amount += iov[index].iov_len; + } + } + + while ((rv = writev(osfd, (const struct iovec*)iov, iov_size)) == -1) { + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, WRITE_FD, timeout))<0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + /* + * optimization; if bytes sent is less than "amount" call + * select before returning. This is because it is likely that + * the next writev() call will return EWOULDBLOCK. + */ + if ((!fd->secret->nonblocking) && (rv > 0) && (rv < amount) + && (timeout != PR_INTERVAL_NO_WAIT)) { + if (_PR_IS_NATIVE_THREAD(me)) { + if (socket_io_wait(osfd, WRITE_FD, timeout) < 0) { + rv = -1; + goto done; + } + } else { + if (local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout) < 0) { + rv = -1; + goto done; + } + } + } + if (rv < 0) { + _PR_MD_MAP_WRITEV_ERROR(err); + } +done: + return(rv); +} + +PRInt32 _MD_accept(PRFileDesc *fd, PRNetAddr *addr, + PRUint32 *addrlen, PRIntervalTime timeout) +{ + PRInt32 osfd = fd->secret->md.osfd; + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); + + while ((rv = accept(osfd, (struct sockaddr *) addr, + (_PRSockLen_t *)addrlen)) == -1) { + err = _MD_ERRNO(); + if ((err == EAGAIN) || (err == EWOULDBLOCK) || (err == ECONNABORTED)) { + if (fd->secret->nonblocking) { + break; + } + if (!_PR_IS_NATIVE_THREAD(me)) { + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_READ, timeout)) < 0) + goto done; + } else { + if ((rv = socket_io_wait(osfd, READ_FD, timeout)) < 0) + goto done; + } + } else if ((err == EINTR) && (!_PR_PENDING_INTERRUPT(me))){ + continue; + } else { + break; + } + } + if (rv < 0) { + _PR_MD_MAP_ACCEPT_ERROR(err); + } +done: +#ifdef _PR_HAVE_SOCKADDR_LEN + if (rv != -1) { + /* ignore the sa_len field of struct sockaddr */ + if (addr) { + addr->raw.family = ((struct sockaddr *) addr)->sa_family; + } + } +#endif /* _PR_HAVE_SOCKADDR_LEN */ + return(rv); +} + +extern int _connect (int s, const struct sockaddr *name, int namelen); +PRInt32 _MD_connect( + PRFileDesc *fd, const PRNetAddr *addr, PRUint32 addrlen, PRIntervalTime timeout) +{ + PRInt32 rv, err; + PRThread *me = _PR_MD_CURRENT_THREAD(); + PRInt32 osfd = fd->secret->md.osfd; +#ifdef IRIX +extern PRInt32 _MD_irix_connect( + PRInt32 osfd, const PRNetAddr *addr, PRInt32 addrlen, PRIntervalTime timeout); +#endif +#ifdef _PR_HAVE_SOCKADDR_LEN + PRNetAddr addrCopy; + + addrCopy = *addr; + ((struct sockaddr *) &addrCopy)->sa_len = addrlen; + ((struct sockaddr *) &addrCopy)->sa_family = addr->raw.family; +#endif + + /* + * We initiate the connection setup by making a nonblocking connect() + * call. If the connect() call fails, there are two cases we handle + * specially: + * 1. The connect() call was interrupted by a signal. In this case + * we simply retry connect(). + * 2. The NSPR socket is nonblocking and connect() fails with + * EINPROGRESS. We first wait until the socket becomes writable. + * Then we try to find out whether the connection setup succeeded + * or failed. + */ + +retry: +#ifdef IRIX + if ((rv = _MD_irix_connect(osfd, addr, addrlen, timeout)) == -1) { +#else +#ifdef _PR_HAVE_SOCKADDR_LEN + if ((rv = connect(osfd, (struct sockaddr *)&addrCopy, addrlen)) == -1) { +#else + if ((rv = connect(osfd, (struct sockaddr *)addr, addrlen)) == -1) { +#endif +#endif + err = _MD_ERRNO(); + + if (err == EINTR) { + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError( PR_PENDING_INTERRUPT_ERROR, 0); + return -1; + } + goto retry; + } + + if (!fd->secret->nonblocking && (err == EINPROGRESS)) { + if (!_PR_IS_NATIVE_THREAD(me)) { + + if ((rv = local_io_wait(osfd, _PR_UNIX_POLL_WRITE, timeout)) < 0) + return -1; + } else { + /* + * socket_io_wait() may return -1 or 1. + */ + + rv = socket_io_wait(osfd, WRITE_FD, timeout); + if (rv == -1) { + return -1; + } + } + + PR_ASSERT(rv == 1); + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError( PR_PENDING_INTERRUPT_ERROR, 0); + return -1; + } + err = _MD_unix_get_nonblocking_connect_error(osfd); + if (err != 0) { + _PR_MD_MAP_CONNECT_ERROR(err); + return -1; + } + return 0; + } + + _PR_MD_MAP_CONNECT_ERROR(err); + } + + return rv; +} /* _MD_connect */ + +PRInt32 _MD_bind(PRFileDesc *fd, const PRNetAddr *addr, PRUint32 addrlen) +{ + PRInt32 rv, err; +#ifdef _PR_HAVE_SOCKADDR_LEN + PRNetAddr addrCopy; + + addrCopy = *addr; + ((struct sockaddr *) &addrCopy)->sa_len = addrlen; + ((struct sockaddr *) &addrCopy)->sa_family = addr->raw.family; + rv = bind(fd->secret->md.osfd, (struct sockaddr *) &addrCopy, (int )addrlen); +#else + rv = bind(fd->secret->md.osfd, (struct sockaddr *) addr, (int )addrlen); +#endif + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_BIND_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_listen(PRFileDesc *fd, PRIntn backlog) +{ + PRInt32 rv, err; + + rv = listen(fd->secret->md.osfd, backlog); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_LISTEN_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_shutdown(PRFileDesc *fd, PRIntn how) +{ + PRInt32 rv, err; + + rv = shutdown(fd->secret->md.osfd, how); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_SHUTDOWN_ERROR(err); + } + return(rv); +} + +PRInt32 _MD_socketpair(int af, int type, int flags, + PRInt32 *osfd) +{ + PRInt32 rv, err; + + rv = socketpair(af, type, flags, osfd); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_SOCKETPAIR_ERROR(err); + } + return rv; +} + +PRStatus _MD_getsockname(PRFileDesc *fd, PRNetAddr *addr, + PRUint32 *addrlen) +{ + PRInt32 rv, err; + + rv = getsockname(fd->secret->md.osfd, + (struct sockaddr *) addr, (_PRSockLen_t *)addrlen); +#ifdef _PR_HAVE_SOCKADDR_LEN + if (rv == 0) { + /* ignore the sa_len field of struct sockaddr */ + if (addr) { + addr->raw.family = ((struct sockaddr *) addr)->sa_family; + } + } +#endif /* _PR_HAVE_SOCKADDR_LEN */ + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_GETSOCKNAME_ERROR(err); + } + return rv==0?PR_SUCCESS:PR_FAILURE; +} + +PRStatus _MD_getpeername(PRFileDesc *fd, PRNetAddr *addr, + PRUint32 *addrlen) +{ + PRInt32 rv, err; + + rv = getpeername(fd->secret->md.osfd, + (struct sockaddr *) addr, (_PRSockLen_t *)addrlen); +#ifdef _PR_HAVE_SOCKADDR_LEN + if (rv == 0) { + /* ignore the sa_len field of struct sockaddr */ + if (addr) { + addr->raw.family = ((struct sockaddr *) addr)->sa_family; + } + } +#endif /* _PR_HAVE_SOCKADDR_LEN */ + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_GETPEERNAME_ERROR(err); + } + return rv==0?PR_SUCCESS:PR_FAILURE; +} + +PRStatus _MD_getsockopt(PRFileDesc *fd, PRInt32 level, + PRInt32 optname, char* optval, PRInt32* optlen) +{ + PRInt32 rv, err; + + rv = getsockopt(fd->secret->md.osfd, level, optname, optval, (_PRSockLen_t *)optlen); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_GETSOCKOPT_ERROR(err); + } + return rv==0?PR_SUCCESS:PR_FAILURE; +} + +PRStatus _MD_setsockopt(PRFileDesc *fd, PRInt32 level, + PRInt32 optname, const char* optval, PRInt32 optlen) +{ + PRInt32 rv, err; + + rv = setsockopt(fd->secret->md.osfd, level, optname, optval, optlen); + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_SETSOCKOPT_ERROR(err); + } + return rv==0?PR_SUCCESS:PR_FAILURE; +} + +PRStatus _MD_set_fd_inheritable(PRFileDesc *fd, PRBool inheritable) +{ + int rv; + + rv = fcntl(fd->secret->md.osfd, F_SETFD, inheritable ? 0 : FD_CLOEXEC); + if (-1 == rv) { + PR_SetError(PR_UNKNOWN_ERROR, _MD_ERRNO()); + return PR_FAILURE; + } + return PR_SUCCESS; +} + +void _MD_init_fd_inheritable(PRFileDesc *fd, PRBool imported) +{ + if (imported) { + fd->secret->inheritable = _PR_TRI_UNKNOWN; + } else { + /* By default, a Unix fd is not closed on exec. */ +#ifdef DEBUG + { + int flags = fcntl(fd->secret->md.osfd, F_GETFD, 0); + PR_ASSERT(0 == flags); + } +#endif + fd->secret->inheritable = _PR_TRI_TRUE; + } +} + +/************************************************************************/ +#if !defined(_PR_USE_POLL) + +/* +** Scan through io queue and find any bad fd's that triggered the error +** from _MD_SELECT +*/ +static void FindBadFDs(void) +{ + PRCList *q; + PRThread *me = _MD_CURRENT_THREAD(); + + PR_ASSERT(!_PR_IS_NATIVE_THREAD(me)); + q = (_PR_IOQ(me->cpu)).next; + _PR_IOQ_MAX_OSFD(me->cpu) = -1; + _PR_IOQ_TIMEOUT(me->cpu) = PR_INTERVAL_NO_TIMEOUT; + while (q != &_PR_IOQ(me->cpu)) { + PRPollQueue *pq = _PR_POLLQUEUE_PTR(q); + PRBool notify = PR_FALSE; + _PRUnixPollDesc *pds = pq->pds; + _PRUnixPollDesc *epds = pds + pq->npds; + PRInt32 pq_max_osfd = -1; + + q = q->next; + for (; pds < epds; pds++) { + PRInt32 osfd = pds->osfd; + pds->out_flags = 0; + PR_ASSERT(osfd >= 0 || pds->in_flags == 0); + if (pds->in_flags == 0) { + continue; /* skip this fd */ + } + if (fcntl(osfd, F_GETFL, 0) == -1) { + /* Found a bad descriptor, remove it from the fd_sets. */ + PR_LOG(_pr_io_lm, PR_LOG_MAX, + ("file descriptor %d is bad", osfd)); + pds->out_flags = _PR_UNIX_POLL_NVAL; + notify = PR_TRUE; + } + if (osfd > pq_max_osfd) { + pq_max_osfd = osfd; + } + } + + if (notify) { + PRIntn pri; + PR_REMOVE_LINK(&pq->links); + pq->on_ioq = PR_FALSE; + + /* + * Decrement the count of descriptors for each desciptor/event + * because this I/O request is being removed from the + * ioq + */ + pds = pq->pds; + for (; pds < epds; pds++) { + PRInt32 osfd = pds->osfd; + PRInt16 in_flags = pds->in_flags; + PR_ASSERT(osfd >= 0 || in_flags == 0); + if (in_flags & _PR_UNIX_POLL_READ) { + if (--(_PR_FD_READ_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_READ_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_WRITE) { + if (--(_PR_FD_WRITE_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_WRITE_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_EXCEPT) { + if (--(_PR_FD_EXCEPTION_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_EXCEPTION_SET(me->cpu)); + } + } + + _PR_THREAD_LOCK(pq->thr); + if (pq->thr->flags & (_PR_ON_PAUSEQ|_PR_ON_SLEEPQ)) { + _PRCPU *cpu = pq->thr->cpu; + _PR_SLEEPQ_LOCK(pq->thr->cpu); + _PR_DEL_SLEEPQ(pq->thr, PR_TRUE); + _PR_SLEEPQ_UNLOCK(pq->thr->cpu); + + if (pq->thr->flags & _PR_SUSPENDING) { + /* + * set thread state to SUSPENDED; + * a Resume operation on the thread + * will move it to the runQ + */ + pq->thr->state = _PR_SUSPENDED; + _PR_MISCQ_LOCK(pq->thr->cpu); + _PR_ADD_SUSPENDQ(pq->thr, pq->thr->cpu); + _PR_MISCQ_UNLOCK(pq->thr->cpu); + } else { + pri = pq->thr->priority; + pq->thr->state = _PR_RUNNABLE; + + _PR_RUNQ_LOCK(cpu); + _PR_ADD_RUNQ(pq->thr, cpu, pri); + _PR_RUNQ_UNLOCK(cpu); + } + } + _PR_THREAD_UNLOCK(pq->thr); + } else { + if (pq->timeout < _PR_IOQ_TIMEOUT(me->cpu)) + _PR_IOQ_TIMEOUT(me->cpu) = pq->timeout; + if (_PR_IOQ_MAX_OSFD(me->cpu) < pq_max_osfd) + _PR_IOQ_MAX_OSFD(me->cpu) = pq_max_osfd; + } + } + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + if (_PR_IOQ_MAX_OSFD(me->cpu) < _pr_md_pipefd[0]) + _PR_IOQ_MAX_OSFD(me->cpu) = _pr_md_pipefd[0]; + } +} +#endif /* !defined(_PR_USE_POLL) */ + +/************************************************************************/ + +/* +** Called by the scheduler when there is nothing to do. This means that +** all threads are blocked on some monitor somewhere. +** +** Note: this code doesn't release the scheduler lock. +*/ +/* +** Pause the current CPU. longjmp to the cpu's pause stack +** +** This must be called with the scheduler locked +*/ +void _MD_PauseCPU(PRIntervalTime ticks) +{ + PRThread *me = _MD_CURRENT_THREAD(); +#ifdef _PR_USE_POLL + int timeout; + struct pollfd *pollfds; /* an array of pollfd structures */ + struct pollfd *pollfdPtr; /* a pointer that steps through the array */ + unsigned long npollfds; /* number of pollfd structures in array */ + unsigned long pollfds_size; + int nfd; /* to hold the return value of poll() */ +#else + struct timeval timeout, *tvp; + fd_set r, w, e; + fd_set *rp, *wp, *ep; + PRInt32 max_osfd, nfd; +#endif /* _PR_USE_POLL */ + PRInt32 rv; + PRCList *q; + PRUint32 min_timeout; + sigset_t oldset; +#ifdef IRIX +extern sigset_t ints_off; +#endif + + PR_ASSERT(_PR_MD_GET_INTSOFF() != 0); + + _PR_MD_IOQ_LOCK(); + +#ifdef _PR_USE_POLL + /* Build up the pollfd structure array to wait on */ + + /* Find out how many pollfd structures are needed */ + npollfds = _PR_IOQ_OSFD_CNT(me->cpu); + PR_ASSERT(npollfds >= 0); + + /* + * We use a pipe to wake up a native thread. An fd is needed + * for the pipe and we poll it for reading. + */ + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + npollfds++; +#ifdef IRIX + /* + * On Irix, a second pipe is used to cause the primordial cpu to + * wakeup and exit, when the process is exiting because of a call + * to exit/PR_ProcessExit. + */ + if (me->cpu->id == 0) { + npollfds++; + } +#endif + } + + /* + * if the cpu's pollfd array is not big enough, release it and allocate a new one + */ + if (npollfds > _PR_IOQ_POLLFDS_SIZE(me->cpu)) { + if (_PR_IOQ_POLLFDS(me->cpu) != NULL) + PR_DELETE(_PR_IOQ_POLLFDS(me->cpu)); + pollfds_size = PR_MAX(_PR_IOQ_MIN_POLLFDS_SIZE(me->cpu), npollfds); + pollfds = (struct pollfd *) PR_MALLOC(pollfds_size * sizeof(struct pollfd)); + _PR_IOQ_POLLFDS(me->cpu) = pollfds; + _PR_IOQ_POLLFDS_SIZE(me->cpu) = pollfds_size; + } else { + pollfds = _PR_IOQ_POLLFDS(me->cpu); + } + pollfdPtr = pollfds; + + /* + * If we need to poll the pipe for waking up a native thread, + * the pipe's fd is the first element in the pollfds array. + */ + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + pollfdPtr->fd = _pr_md_pipefd[0]; + pollfdPtr->events = POLLIN; + pollfdPtr++; +#ifdef IRIX + /* + * On Irix, the second element is the exit pipe + */ + if (me->cpu->id == 0) { + pollfdPtr->fd = _pr_irix_primoridal_cpu_fd[0]; + pollfdPtr->events = POLLIN; + pollfdPtr++; + } +#endif + } + + min_timeout = PR_INTERVAL_NO_TIMEOUT; + for (q = _PR_IOQ(me->cpu).next; q != &_PR_IOQ(me->cpu); q = q->next) { + PRPollQueue *pq = _PR_POLLQUEUE_PTR(q); + _PRUnixPollDesc *pds = pq->pds; + _PRUnixPollDesc *epds = pds + pq->npds; + + if (pq->timeout < min_timeout) { + min_timeout = pq->timeout; + } + for (; pds < epds; pds++, pollfdPtr++) { + /* + * Assert that the pollfdPtr pointer does not go + * beyond the end of the pollfds array + */ + PR_ASSERT(pollfdPtr < pollfds + npollfds); + pollfdPtr->fd = pds->osfd; + /* direct copy of poll flags */ + pollfdPtr->events = pds->in_flags; + } + } + _PR_IOQ_TIMEOUT(me->cpu) = min_timeout; +#else + /* + * assigment of fd_sets + */ + r = _PR_FD_READ_SET(me->cpu); + w = _PR_FD_WRITE_SET(me->cpu); + e = _PR_FD_EXCEPTION_SET(me->cpu); + + rp = &r; + wp = &w; + ep = &e; + + max_osfd = _PR_IOQ_MAX_OSFD(me->cpu) + 1; + min_timeout = _PR_IOQ_TIMEOUT(me->cpu); +#endif /* _PR_USE_POLL */ + /* + ** Compute the minimum timeout value: make it the smaller of the + ** timeouts specified by the i/o pollers or the timeout of the first + ** sleeping thread. + */ + q = _PR_SLEEPQ(me->cpu).next; + + if (q != &_PR_SLEEPQ(me->cpu)) { + PRThread *t = _PR_THREAD_PTR(q); + + if (t->sleep < min_timeout) { + min_timeout = t->sleep; + } + } + if (min_timeout > ticks) { + min_timeout = ticks; + } + +#ifdef _PR_USE_POLL + if (min_timeout == PR_INTERVAL_NO_TIMEOUT) + timeout = -1; + else + timeout = PR_IntervalToMilliseconds(min_timeout); +#else + if (min_timeout == PR_INTERVAL_NO_TIMEOUT) { + tvp = NULL; + } else { + timeout.tv_sec = PR_IntervalToSeconds(min_timeout); + timeout.tv_usec = PR_IntervalToMicroseconds(min_timeout) + % PR_USEC_PER_SEC; + tvp = &timeout; + } +#endif /* _PR_USE_POLL */ + + _PR_MD_IOQ_UNLOCK(); + _MD_CHECK_FOR_EXIT(); + /* + * check for i/o operations + */ +#ifndef _PR_NO_CLOCK_TIMER + /* + * Disable the clock interrupts while we are in select, if clock interrupts + * are enabled. Otherwise, when the select/poll calls are interrupted, the + * timer value starts ticking from zero again when the system call is restarted. + */ +#ifdef IRIX + /* + * SIGCHLD signal is used on Irix to detect he termination of an + * sproc by SIGSEGV, SIGBUS or SIGABRT signals when + * _nspr_terminate_on_error is set. + */ + if ((!_nspr_noclock) || (_nspr_terminate_on_error)) +#else + if (!_nspr_noclock) +#endif /* IRIX */ +#ifdef IRIX + sigprocmask(SIG_BLOCK, &ints_off, &oldset); +#else + PR_ASSERT(sigismember(&timer_set, SIGALRM)); + sigprocmask(SIG_BLOCK, &timer_set, &oldset); +#endif /* IRIX */ +#endif /* !_PR_NO_CLOCK_TIMER */ + +#ifndef _PR_USE_POLL + PR_ASSERT(FD_ISSET(_pr_md_pipefd[0],rp)); + nfd = _MD_SELECT(max_osfd, rp, wp, ep, tvp); +#else + nfd = _MD_POLL(pollfds, npollfds, timeout); +#endif /* !_PR_USE_POLL */ + +#ifndef _PR_NO_CLOCK_TIMER +#ifdef IRIX + if ((!_nspr_noclock) || (_nspr_terminate_on_error)) +#else + if (!_nspr_noclock) +#endif /* IRIX */ + sigprocmask(SIG_SETMASK, &oldset, 0); +#endif /* !_PR_NO_CLOCK_TIMER */ + + _MD_CHECK_FOR_EXIT(); + +#ifdef IRIX + _PR_MD_primordial_cpu(); +#endif + + _PR_MD_IOQ_LOCK(); + /* + ** Notify monitors that are associated with the selected descriptors. + */ +#ifdef _PR_USE_POLL + if (nfd > 0) { + pollfdPtr = pollfds; + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + /* + * Assert that the pipe is the first element in the + * pollfds array. + */ + PR_ASSERT(pollfds[0].fd == _pr_md_pipefd[0]); + if ((pollfds[0].revents & POLLIN) && (nfd == 1)) { + /* + * woken up by another thread; read all the data + * in the pipe to empty the pipe + */ + while ((rv = read(_pr_md_pipefd[0], _pr_md_pipebuf, + PIPE_BUF)) == PIPE_BUF){ + } + PR_ASSERT((rv > 0) || ((rv == -1) && (errno == EAGAIN))); + } + pollfdPtr++; +#ifdef IRIX + /* + * On Irix, check to see if the primordial cpu needs to exit + * to cause the process to terminate + */ + if (me->cpu->id == 0) { + PR_ASSERT(pollfds[1].fd == _pr_irix_primoridal_cpu_fd[0]); + if (pollfdPtr->revents & POLLIN) { + if (_pr_irix_process_exit) { + /* + * process exit due to a call to PR_ProcessExit + */ + prctl(PR_SETEXITSIG, SIGKILL); + _exit(_pr_irix_process_exit_code); + } else { + while ((rv = read(_pr_irix_primoridal_cpu_fd[0], + _pr_md_pipebuf, PIPE_BUF)) == PIPE_BUF) { + } + PR_ASSERT(rv > 0); + } + } + pollfdPtr++; + } +#endif + } + for (q = _PR_IOQ(me->cpu).next; q != &_PR_IOQ(me->cpu); q = q->next) { + PRPollQueue *pq = _PR_POLLQUEUE_PTR(q); + PRBool notify = PR_FALSE; + _PRUnixPollDesc *pds = pq->pds; + _PRUnixPollDesc *epds = pds + pq->npds; + + for (; pds < epds; pds++, pollfdPtr++) { + /* + * Assert that the pollfdPtr pointer does not go beyond + * the end of the pollfds array. + */ + PR_ASSERT(pollfdPtr < pollfds + npollfds); + /* + * Assert that the fd's in the pollfds array (stepped + * through by pollfdPtr) are in the same order as + * the fd's in _PR_IOQ() (stepped through by q and pds). + * This is how the pollfds array was created earlier. + */ + PR_ASSERT(pollfdPtr->fd == pds->osfd); + pds->out_flags = pollfdPtr->revents; + /* Negative fd's are ignored by poll() */ + if (pds->osfd >= 0 && pds->out_flags) { + notify = PR_TRUE; + } + } + if (notify) { + PRIntn pri; + PRThread *thred; + + PR_REMOVE_LINK(&pq->links); + pq->on_ioq = PR_FALSE; + + thred = pq->thr; + _PR_THREAD_LOCK(thred); + if (pq->thr->flags & (_PR_ON_PAUSEQ|_PR_ON_SLEEPQ)) { + _PRCPU *cpu = pq->thr->cpu; + _PR_SLEEPQ_LOCK(pq->thr->cpu); + _PR_DEL_SLEEPQ(pq->thr, PR_TRUE); + _PR_SLEEPQ_UNLOCK(pq->thr->cpu); + + if (pq->thr->flags & _PR_SUSPENDING) { + /* + * set thread state to SUSPENDED; + * a Resume operation on the thread + * will move it to the runQ + */ + pq->thr->state = _PR_SUSPENDED; + _PR_MISCQ_LOCK(pq->thr->cpu); + _PR_ADD_SUSPENDQ(pq->thr, pq->thr->cpu); + _PR_MISCQ_UNLOCK(pq->thr->cpu); + } else { + pri = pq->thr->priority; + pq->thr->state = _PR_RUNNABLE; + + _PR_RUNQ_LOCK(cpu); + _PR_ADD_RUNQ(pq->thr, cpu, pri); + _PR_RUNQ_UNLOCK(cpu); + if (_pr_md_idle_cpus > 1) + _PR_MD_WAKEUP_WAITER(thred); + } + } + _PR_THREAD_UNLOCK(thred); + _PR_IOQ_OSFD_CNT(me->cpu) -= pq->npds; + PR_ASSERT(_PR_IOQ_OSFD_CNT(me->cpu) >= 0); + } + } + } else if (nfd == -1) { + PR_LOG(_pr_io_lm, PR_LOG_MAX, ("poll() failed with errno %d", errno)); + } + +#else + if (nfd > 0) { + q = _PR_IOQ(me->cpu).next; + _PR_IOQ_MAX_OSFD(me->cpu) = -1; + _PR_IOQ_TIMEOUT(me->cpu) = PR_INTERVAL_NO_TIMEOUT; + while (q != &_PR_IOQ(me->cpu)) { + PRPollQueue *pq = _PR_POLLQUEUE_PTR(q); + PRBool notify = PR_FALSE; + _PRUnixPollDesc *pds = pq->pds; + _PRUnixPollDesc *epds = pds + pq->npds; + PRInt32 pq_max_osfd = -1; + + q = q->next; + for (; pds < epds; pds++) { + PRInt32 osfd = pds->osfd; + PRInt16 in_flags = pds->in_flags; + PRInt16 out_flags = 0; + PR_ASSERT(osfd >= 0 || in_flags == 0); + if ((in_flags & _PR_UNIX_POLL_READ) && FD_ISSET(osfd, rp)) { + out_flags |= _PR_UNIX_POLL_READ; + } + if ((in_flags & _PR_UNIX_POLL_WRITE) && FD_ISSET(osfd, wp)) { + out_flags |= _PR_UNIX_POLL_WRITE; + } + if ((in_flags & _PR_UNIX_POLL_EXCEPT) && FD_ISSET(osfd, ep)) { + out_flags |= _PR_UNIX_POLL_EXCEPT; + } + pds->out_flags = out_flags; + if (out_flags) { + notify = PR_TRUE; + } + if (osfd > pq_max_osfd) { + pq_max_osfd = osfd; + } + } + if (notify == PR_TRUE) { + PRIntn pri; + PRThread *thred; + + PR_REMOVE_LINK(&pq->links); + pq->on_ioq = PR_FALSE; + + /* + * Decrement the count of descriptors for each desciptor/event + * because this I/O request is being removed from the + * ioq + */ + pds = pq->pds; + for (; pds < epds; pds++) { + PRInt32 osfd = pds->osfd; + PRInt16 in_flags = pds->in_flags; + PR_ASSERT(osfd >= 0 || in_flags == 0); + if (in_flags & _PR_UNIX_POLL_READ) { + if (--(_PR_FD_READ_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_READ_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_WRITE) { + if (--(_PR_FD_WRITE_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_WRITE_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_EXCEPT) { + if (--(_PR_FD_EXCEPTION_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_EXCEPTION_SET(me->cpu)); + } + } + + /* + * Because this thread can run on a different cpu right + * after being added to the run queue, do not dereference + * pq + */ + thred = pq->thr; + _PR_THREAD_LOCK(thred); + if (pq->thr->flags & (_PR_ON_PAUSEQ|_PR_ON_SLEEPQ)) { + _PRCPU *cpu = thred->cpu; + _PR_SLEEPQ_LOCK(pq->thr->cpu); + _PR_DEL_SLEEPQ(pq->thr, PR_TRUE); + _PR_SLEEPQ_UNLOCK(pq->thr->cpu); + + if (pq->thr->flags & _PR_SUSPENDING) { + /* + * set thread state to SUSPENDED; + * a Resume operation on the thread + * will move it to the runQ + */ + pq->thr->state = _PR_SUSPENDED; + _PR_MISCQ_LOCK(pq->thr->cpu); + _PR_ADD_SUSPENDQ(pq->thr, pq->thr->cpu); + _PR_MISCQ_UNLOCK(pq->thr->cpu); + } else { + pri = pq->thr->priority; + pq->thr->state = _PR_RUNNABLE; + + pq->thr->cpu = cpu; + _PR_RUNQ_LOCK(cpu); + _PR_ADD_RUNQ(pq->thr, cpu, pri); + _PR_RUNQ_UNLOCK(cpu); + if (_pr_md_idle_cpus > 1) + _PR_MD_WAKEUP_WAITER(thred); + } + } + _PR_THREAD_UNLOCK(thred); + } else { + if (pq->timeout < _PR_IOQ_TIMEOUT(me->cpu)) + _PR_IOQ_TIMEOUT(me->cpu) = pq->timeout; + if (_PR_IOQ_MAX_OSFD(me->cpu) < pq_max_osfd) + _PR_IOQ_MAX_OSFD(me->cpu) = pq_max_osfd; + } + } + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + if ((FD_ISSET(_pr_md_pipefd[0], rp)) && (nfd == 1)) { + /* + * woken up by another thread; read all the data + * in the pipe to empty the pipe + */ + while ((rv = + read(_pr_md_pipefd[0], _pr_md_pipebuf, PIPE_BUF)) + == PIPE_BUF){ + } + PR_ASSERT((rv > 0) || + ((rv == -1) && (errno == EAGAIN))); + } + if (_PR_IOQ_MAX_OSFD(me->cpu) < _pr_md_pipefd[0]) + _PR_IOQ_MAX_OSFD(me->cpu) = _pr_md_pipefd[0]; +#ifdef IRIX + if ((me->cpu->id == 0) && + (FD_ISSET(_pr_irix_primoridal_cpu_fd[0], rp))) { + if (_pr_irix_process_exit) { + /* + * process exit due to a call to PR_ProcessExit + */ + prctl(PR_SETEXITSIG, SIGKILL); + _exit(_pr_irix_process_exit_code); + } else { + while ((rv = read(_pr_irix_primoridal_cpu_fd[0], + _pr_md_pipebuf, PIPE_BUF)) == PIPE_BUF) { + } + PR_ASSERT(rv > 0); + } + } + if (me->cpu->id == 0) { + if (_PR_IOQ_MAX_OSFD(me->cpu) < _pr_irix_primoridal_cpu_fd[0]) + _PR_IOQ_MAX_OSFD(me->cpu) = _pr_irix_primoridal_cpu_fd[0]; + } +#endif + } + } else if (nfd < 0) { + if (errno == EBADF) { + FindBadFDs(); + } else { + PR_LOG(_pr_io_lm, PR_LOG_MAX, ("select() failed with errno %d", + errno)); + } + } else { + PR_ASSERT(nfd == 0); + /* + * compute the new value of _PR_IOQ_TIMEOUT + */ + q = _PR_IOQ(me->cpu).next; + _PR_IOQ_MAX_OSFD(me->cpu) = -1; + _PR_IOQ_TIMEOUT(me->cpu) = PR_INTERVAL_NO_TIMEOUT; + while (q != &_PR_IOQ(me->cpu)) { + PRPollQueue *pq = _PR_POLLQUEUE_PTR(q); + _PRUnixPollDesc *pds = pq->pds; + _PRUnixPollDesc *epds = pds + pq->npds; + PRInt32 pq_max_osfd = -1; + + q = q->next; + for (; pds < epds; pds++) { + if (pds->osfd > pq_max_osfd) { + pq_max_osfd = pds->osfd; + } + } + if (pq->timeout < _PR_IOQ_TIMEOUT(me->cpu)) + _PR_IOQ_TIMEOUT(me->cpu) = pq->timeout; + if (_PR_IOQ_MAX_OSFD(me->cpu) < pq_max_osfd) + _PR_IOQ_MAX_OSFD(me->cpu) = pq_max_osfd; + } + if (_PR_IS_NATIVE_THREAD_SUPPORTED()) { + if (_PR_IOQ_MAX_OSFD(me->cpu) < _pr_md_pipefd[0]) + _PR_IOQ_MAX_OSFD(me->cpu) = _pr_md_pipefd[0]; + } + } +#endif /* _PR_USE_POLL */ + _PR_MD_IOQ_UNLOCK(); +} + +void _MD_Wakeup_CPUs() +{ + PRInt32 rv, data; + + data = 0; + rv = write(_pr_md_pipefd[1], &data, 1); + + while ((rv < 0) && (errno == EAGAIN)) { + /* + * pipe full, read all data in pipe to empty it + */ + while ((rv = + read(_pr_md_pipefd[0], _pr_md_pipebuf, PIPE_BUF)) + == PIPE_BUF) { + } + PR_ASSERT((rv > 0) || + ((rv == -1) && (errno == EAGAIN))); + rv = write(_pr_md_pipefd[1], &data, 1); + } +} + + +void _MD_InitCPUS() +{ + PRInt32 rv, flags; + PRThread *me = _MD_CURRENT_THREAD(); + + rv = pipe(_pr_md_pipefd); + PR_ASSERT(rv == 0); + _PR_IOQ_MAX_OSFD(me->cpu) = _pr_md_pipefd[0]; +#ifndef _PR_USE_POLL + FD_SET(_pr_md_pipefd[0], &_PR_FD_READ_SET(me->cpu)); +#endif + + flags = fcntl(_pr_md_pipefd[0], F_GETFL, 0); + fcntl(_pr_md_pipefd[0], F_SETFL, flags | O_NONBLOCK); + flags = fcntl(_pr_md_pipefd[1], F_GETFL, 0); + fcntl(_pr_md_pipefd[1], F_SETFL, flags | O_NONBLOCK); +} + +/* +** Unix SIGALRM (clock) signal handler +*/ +static void ClockInterruptHandler() +{ + int olderrno; + PRUintn pri; + _PRCPU *cpu = _PR_MD_CURRENT_CPU(); + PRThread *me = _MD_CURRENT_THREAD(); + +#ifdef SOLARIS + if (!me || _PR_IS_NATIVE_THREAD(me)) { + _pr_primordialCPU->u.missed[_pr_primordialCPU->where] |= _PR_MISSED_CLOCK; + return; + } +#endif + + if (_PR_MD_GET_INTSOFF() != 0) { + cpu->u.missed[cpu->where] |= _PR_MISSED_CLOCK; + return; + } + _PR_MD_SET_INTSOFF(1); + + olderrno = errno; + _PR_ClockInterrupt(); + errno = olderrno; + + /* + ** If the interrupt wants a resched or if some other thread at + ** the same priority needs the cpu, reschedule. + */ + pri = me->priority; + if ((cpu->u.missed[3] || (_PR_RUNQREADYMASK(me->cpu) >> pri))) { +#ifdef _PR_NO_PREEMPT + cpu->resched = PR_TRUE; + if (pr_interruptSwitchHook) { + (*pr_interruptSwitchHook)(pr_interruptSwitchHookArg); + } +#else /* _PR_NO_PREEMPT */ + /* + ** Re-enable unix interrupts (so that we can use + ** setjmp/longjmp for context switching without having to + ** worry about the signal state) + */ + sigprocmask(SIG_SETMASK, &empty_set, 0); + PR_LOG(_pr_sched_lm, PR_LOG_MIN, ("clock caused context switch")); + + if(!(me->flags & _PR_IDLE_THREAD)) { + _PR_THREAD_LOCK(me); + me->state = _PR_RUNNABLE; + me->cpu = cpu; + _PR_RUNQ_LOCK(cpu); + _PR_ADD_RUNQ(me, cpu, pri); + _PR_RUNQ_UNLOCK(cpu); + _PR_THREAD_UNLOCK(me); + } else + me->state = _PR_RUNNABLE; + _MD_SWITCH_CONTEXT(me); + PR_LOG(_pr_sched_lm, PR_LOG_MIN, ("clock back from context switch")); +#endif /* _PR_NO_PREEMPT */ + } + /* + * Because this thread could be running on a different cpu after + * a context switch the current cpu should be accessed and the + * value of the 'cpu' variable should not be used. + */ + _PR_MD_SET_INTSOFF(0); +} + +/* + * On HP-UX 9, we have to use the sigvector() interface to restart + * interrupted system calls, because sigaction() does not have the + * SA_RESTART flag. + */ + +#ifdef HPUX9 +static void HPUX9_ClockInterruptHandler( + int sig, + int code, + struct sigcontext *scp) +{ + ClockInterruptHandler(); + scp->sc_syscall_action = SIG_RESTART; +} +#endif /* HPUX9 */ + +/* # of milliseconds per clock tick that we will use */ +#define MSEC_PER_TICK 50 + + +void _MD_StartInterrupts() +{ + char *eval; + + if ((eval = getenv("NSPR_NOCLOCK")) != NULL) { + if (atoi(eval) == 0) + _nspr_noclock = 0; + else + _nspr_noclock = 1; + } + +#ifndef _PR_NO_CLOCK_TIMER + if (!_nspr_noclock) { + _MD_EnableClockInterrupts(); + } +#endif +} + +void _MD_StopInterrupts() +{ + sigprocmask(SIG_BLOCK, &timer_set, 0); +} + +void _MD_EnableClockInterrupts() +{ + struct itimerval itval; + extern PRUintn _pr_numCPU; +#ifdef HPUX9 + struct sigvec vec; + + vec.sv_handler = (void (*)()) HPUX9_ClockInterruptHandler; + vec.sv_mask = 0; + vec.sv_flags = 0; + sigvector(SIGALRM, &vec, 0); +#else + struct sigaction vtact; + + vtact.sa_handler = (void (*)()) ClockInterruptHandler; + sigemptyset(&vtact.sa_mask); + vtact.sa_flags = SA_RESTART; + sigaction(SIGALRM, &vtact, 0); +#endif /* HPUX9 */ + + PR_ASSERT(_pr_numCPU == 1); + itval.it_interval.tv_sec = 0; + itval.it_interval.tv_usec = MSEC_PER_TICK * PR_USEC_PER_MSEC; + itval.it_value = itval.it_interval; + setitimer(ITIMER_REAL, &itval, 0); +} + +void _MD_DisableClockInterrupts() +{ + struct itimerval itval; + extern PRUintn _pr_numCPU; + + PR_ASSERT(_pr_numCPU == 1); + itval.it_interval.tv_sec = 0; + itval.it_interval.tv_usec = 0; + itval.it_value = itval.it_interval; + setitimer(ITIMER_REAL, &itval, 0); +} + +void _MD_BlockClockInterrupts() +{ + sigprocmask(SIG_BLOCK, &timer_set, 0); +} + +void _MD_UnblockClockInterrupts() +{ + sigprocmask(SIG_UNBLOCK, &timer_set, 0); +} + +void _MD_MakeNonblock(PRFileDesc *fd) +{ + PRInt32 osfd = fd->secret->md.osfd; + int flags; + + if (osfd <= 2) { + /* Don't mess around with stdin, stdout or stderr */ + return; + } + flags = fcntl(osfd, F_GETFL, 0); + + /* + * Use O_NONBLOCK (POSIX-style non-blocking I/O) whenever possible. + * On SunOS 4, we must use FNDELAY (BSD-style non-blocking I/O), + * otherwise connect() still blocks and can be interrupted by SIGALRM. + */ + + fcntl(osfd, F_SETFL, flags | O_NONBLOCK); + } + +PRInt32 _MD_open(const char *name, PRIntn flags, PRIntn mode) +{ + PRInt32 osflags; + PRInt32 rv, err; + + if (flags & PR_RDWR) { + osflags = O_RDWR; + } else if (flags & PR_WRONLY) { + osflags = O_WRONLY; + } else { + osflags = O_RDONLY; + } + + if (flags & PR_EXCL) + osflags |= O_EXCL; + if (flags & PR_APPEND) + osflags |= O_APPEND; + if (flags & PR_TRUNCATE) + osflags |= O_TRUNC; + if (flags & PR_SYNC) { +#if defined(O_SYNC) + osflags |= O_SYNC; +#elif defined(O_FSYNC) + osflags |= O_FSYNC; +#else +#error "Neither O_SYNC nor O_FSYNC is defined on this platform" +#endif + } + + /* + ** On creations we hold the 'create' lock in order to enforce + ** the semantics of PR_Rename. (see the latter for more details) + */ + if (flags & PR_CREATE_FILE) + { + osflags |= O_CREAT; + if (NULL !=_pr_rename_lock) + PR_Lock(_pr_rename_lock); + } + +#if defined(ANDROID) + osflags |= O_LARGEFILE; +#endif + + rv = _md_iovector._open64(name, osflags, mode); + + if (rv < 0) { + err = _MD_ERRNO(); + _PR_MD_MAP_OPEN_ERROR(err); + } + + if ((flags & PR_CREATE_FILE) && (NULL !=_pr_rename_lock)) + PR_Unlock(_pr_rename_lock); + return rv; +} + +PRIntervalTime intr_timeout_ticks; + +#if defined(SOLARIS) || defined(IRIX) +static void sigsegvhandler() { + fprintf(stderr,"Received SIGSEGV\n"); + fflush(stderr); + pause(); +} + +static void sigaborthandler() { + fprintf(stderr,"Received SIGABRT\n"); + fflush(stderr); + pause(); +} + +static void sigbushandler() { + fprintf(stderr,"Received SIGBUS\n"); + fflush(stderr); + pause(); +} +#endif /* SOLARIS, IRIX */ + +#endif /* !defined(_PR_PTHREADS) */ + +void _MD_query_fd_inheritable(PRFileDesc *fd) +{ + int flags; + + PR_ASSERT(_PR_TRI_UNKNOWN == fd->secret->inheritable); + flags = fcntl(fd->secret->md.osfd, F_GETFD, 0); + PR_ASSERT(-1 != flags); + fd->secret->inheritable = (flags & FD_CLOEXEC) ? + _PR_TRI_FALSE : _PR_TRI_TRUE; +} + +PROffset32 _MD_lseek(PRFileDesc *fd, PROffset32 offset, PRSeekWhence whence) +{ + PROffset32 rv, where; + + switch (whence) { + case PR_SEEK_SET: + where = SEEK_SET; + break; + case PR_SEEK_CUR: + where = SEEK_CUR; + break; + case PR_SEEK_END: + where = SEEK_END; + break; + default: + PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); + rv = -1; + goto done; + } + rv = lseek(fd->secret->md.osfd,offset,where); + if (rv == -1) + { + PRInt32 syserr = _MD_ERRNO(); + _PR_MD_MAP_LSEEK_ERROR(syserr); + } +done: + return(rv); +} + +PROffset64 _MD_lseek64(PRFileDesc *fd, PROffset64 offset, PRSeekWhence whence) +{ + PRInt32 where; + PROffset64 rv; + + switch (whence) + { + case PR_SEEK_SET: + where = SEEK_SET; + break; + case PR_SEEK_CUR: + where = SEEK_CUR; + break; + case PR_SEEK_END: + where = SEEK_END; + break; + default: + PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); + rv = minus_one; + goto done; + } + rv = _md_iovector._lseek64(fd->secret->md.osfd, offset, where); + if (LL_EQ(rv, minus_one)) + { + PRInt32 syserr = _MD_ERRNO(); + _PR_MD_MAP_LSEEK_ERROR(syserr); + } +done: + return rv; +} /* _MD_lseek64 */ + +/* +** _MD_set_fileinfo_times -- +** Set the modifyTime and creationTime of the PRFileInfo +** structure using the values in struct stat. +** +** _MD_set_fileinfo64_times -- +** Set the modifyTime and creationTime of the PRFileInfo64 +** structure using the values in _MDStat64. +*/ + +#if defined(_PR_STAT_HAS_ST_ATIM) +/* +** struct stat has st_atim, st_mtim, and st_ctim fields of +** type timestruc_t. +*/ +static void _MD_set_fileinfo_times( + const struct stat *sb, + PRFileInfo *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtim.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtim.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctim.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctim.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} + +static void _MD_set_fileinfo64_times( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtim.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtim.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctim.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctim.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} +#elif defined(_PR_STAT_HAS_ST_ATIM_UNION) +/* +** The st_atim, st_mtim, and st_ctim fields in struct stat are +** unions with a st__tim union member of type timestruc_t. +*/ +static void _MD_set_fileinfo_times( + const struct stat *sb, + PRFileInfo *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtim.st__tim.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtim.st__tim.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctim.st__tim.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctim.st__tim.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} + +static void _MD_set_fileinfo64_times( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtim.st__tim.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtim.st__tim.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctim.st__tim.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctim.st__tim.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} +#elif defined(_PR_STAT_HAS_ST_ATIMESPEC) +/* +** struct stat has st_atimespec, st_mtimespec, and st_ctimespec +** fields of type struct timespec. +*/ +#if defined(_PR_TIMESPEC_HAS_TS_SEC) +static void _MD_set_fileinfo_times( + const struct stat *sb, + PRFileInfo *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtimespec.ts_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtimespec.ts_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctimespec.ts_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctimespec.ts_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} + +static void _MD_set_fileinfo64_times( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtimespec.ts_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtimespec.ts_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctimespec.ts_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctimespec.ts_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} +#else /* _PR_TIMESPEC_HAS_TS_SEC */ +/* +** The POSIX timespec structure has tv_sec and tv_nsec. +*/ +static void _MD_set_fileinfo_times( + const struct stat *sb, + PRFileInfo *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtimespec.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtimespec.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctimespec.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctimespec.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} + +static void _MD_set_fileinfo64_times( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + PRInt64 us, s2us; + + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(info->modifyTime, sb->st_mtimespec.tv_sec); + LL_MUL(info->modifyTime, info->modifyTime, s2us); + LL_I2L(us, sb->st_mtimespec.tv_nsec / 1000); + LL_ADD(info->modifyTime, info->modifyTime, us); + LL_I2L(info->creationTime, sb->st_ctimespec.tv_sec); + LL_MUL(info->creationTime, info->creationTime, s2us); + LL_I2L(us, sb->st_ctimespec.tv_nsec / 1000); + LL_ADD(info->creationTime, info->creationTime, us); +} +#endif /* _PR_TIMESPEC_HAS_TS_SEC */ +#elif defined(_PR_STAT_HAS_ONLY_ST_ATIME) +/* +** struct stat only has st_atime, st_mtime, and st_ctime fields +** of type time_t. +*/ +static void _MD_set_fileinfo_times( + const struct stat *sb, + PRFileInfo *info) +{ + PRInt64 s, s2us; + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(s, sb->st_mtime); + LL_MUL(s, s, s2us); + info->modifyTime = s; + LL_I2L(s, sb->st_ctime); + LL_MUL(s, s, s2us); + info->creationTime = s; +} + +static void _MD_set_fileinfo64_times( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + PRInt64 s, s2us; + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(s, sb->st_mtime); + LL_MUL(s, s, s2us); + info->modifyTime = s; + LL_I2L(s, sb->st_ctime); + LL_MUL(s, s, s2us); + info->creationTime = s; +} +#else +#error "I don't know yet" +#endif + +static int _MD_convert_stat_to_fileinfo( + const struct stat *sb, + PRFileInfo *info) +{ + if (S_IFREG & sb->st_mode) + info->type = PR_FILE_FILE; + else if (S_IFDIR & sb->st_mode) + info->type = PR_FILE_DIRECTORY; + else + info->type = PR_FILE_OTHER; + +#if defined(_PR_HAVE_LARGE_OFF_T) + if (0x7fffffffL < sb->st_size) + { + PR_SetError(PR_FILE_TOO_BIG_ERROR, 0); + return -1; + } +#endif /* defined(_PR_HAVE_LARGE_OFF_T) */ + info->size = sb->st_size; + + _MD_set_fileinfo_times(sb, info); + return 0; +} /* _MD_convert_stat_to_fileinfo */ + +static int _MD_convert_stat64_to_fileinfo64( + const _MDStat64 *sb, + PRFileInfo64 *info) +{ + if (S_IFREG & sb->st_mode) + info->type = PR_FILE_FILE; + else if (S_IFDIR & sb->st_mode) + info->type = PR_FILE_DIRECTORY; + else + info->type = PR_FILE_OTHER; + + LL_I2L(info->size, sb->st_size); + + _MD_set_fileinfo64_times(sb, info); + return 0; +} /* _MD_convert_stat64_to_fileinfo64 */ + +PRInt32 _MD_getfileinfo(const char *fn, PRFileInfo *info) +{ + PRInt32 rv; + struct stat sb; + + rv = stat(fn, &sb); + if (rv < 0) + _PR_MD_MAP_STAT_ERROR(_MD_ERRNO()); + else if (NULL != info) + rv = _MD_convert_stat_to_fileinfo(&sb, info); + return rv; +} + +PRInt32 _MD_getfileinfo64(const char *fn, PRFileInfo64 *info) +{ + _MDStat64 sb; + PRInt32 rv = _md_iovector._stat64(fn, &sb); + if (rv < 0) + _PR_MD_MAP_STAT_ERROR(_MD_ERRNO()); + else if (NULL != info) + rv = _MD_convert_stat64_to_fileinfo64(&sb, info); + return rv; +} + +PRInt32 _MD_getopenfileinfo(const PRFileDesc *fd, PRFileInfo *info) +{ + struct stat sb; + PRInt32 rv = fstat(fd->secret->md.osfd, &sb); + if (rv < 0) + _PR_MD_MAP_FSTAT_ERROR(_MD_ERRNO()); + else if (NULL != info) + rv = _MD_convert_stat_to_fileinfo(&sb, info); + return rv; +} + +PRInt32 _MD_getopenfileinfo64(const PRFileDesc *fd, PRFileInfo64 *info) +{ + _MDStat64 sb; + PRInt32 rv = _md_iovector._fstat64(fd->secret->md.osfd, &sb); + if (rv < 0) + _PR_MD_MAP_FSTAT_ERROR(_MD_ERRNO()); + else if (NULL != info) + rv = _MD_convert_stat64_to_fileinfo64(&sb, info); + return rv; +} + +/* + * _md_iovector._open64 must be initialized to 'open' so that _PR_InitLog can + * open the log file during NSPR initialization, before _md_iovector is + * initialized by _PR_MD_FINAL_INIT. This means the log file cannot be a + * large file on some platforms. + */ +#ifdef SYMBIAN +struct _MD_IOVector _md_iovector; /* Will crash if NSPR_LOG_FILE is set. */ +#else +struct _MD_IOVector _md_iovector = { open }; +#endif + +/* +** These implementations are to emulate large file routines on systems that +** don't have them. Their goal is to check in case overflow occurs. Otherwise +** they will just operate as normal using 32-bit file routines. +** +** The checking might be pre- or post-op, depending on the semantics. +*/ + +#if defined(SOLARIS2_5) + +static PRIntn _MD_solaris25_fstat64(PRIntn osfd, _MDStat64 *buf) +{ + PRInt32 rv; + struct stat sb; + + rv = fstat(osfd, &sb); + if (rv >= 0) + { + /* + ** I'm only copying the fields that are immediately needed. + ** If somebody else calls this function, some of the fields + ** may not be defined. + */ + (void)memset(buf, 0, sizeof(_MDStat64)); + buf->st_mode = sb.st_mode; + buf->st_ctim = sb.st_ctim; + buf->st_mtim = sb.st_mtim; + buf->st_size = sb.st_size; + } + return rv; +} /* _MD_solaris25_fstat64 */ + +static PRIntn _MD_solaris25_stat64(const char *fn, _MDStat64 *buf) +{ + PRInt32 rv; + struct stat sb; + + rv = stat(fn, &sb); + if (rv >= 0) + { + /* + ** I'm only copying the fields that are immediately needed. + ** If somebody else calls this function, some of the fields + ** may not be defined. + */ + (void)memset(buf, 0, sizeof(_MDStat64)); + buf->st_mode = sb.st_mode; + buf->st_ctim = sb.st_ctim; + buf->st_mtim = sb.st_mtim; + buf->st_size = sb.st_size; + } + return rv; +} /* _MD_solaris25_stat64 */ +#endif /* defined(SOLARIS2_5) */ + +#if defined(_PR_NO_LARGE_FILES) || defined(SOLARIS2_5) + +static PROffset64 _MD_Unix_lseek64(PRIntn osfd, PROffset64 offset, PRIntn whence) +{ + PRUint64 maxoff; + PROffset64 rv = minus_one; + LL_I2L(maxoff, 0x7fffffff); + if (LL_CMP(offset, <=, maxoff)) + { + off_t off; + LL_L2I(off, offset); + LL_I2L(rv, lseek(osfd, off, whence)); + } + else errno = EFBIG; /* we can't go there */ + return rv; +} /* _MD_Unix_lseek64 */ + +static void* _MD_Unix_mmap64( + void *addr, PRSize len, PRIntn prot, PRIntn flags, + PRIntn fildes, PRInt64 offset) +{ + PR_SetError(PR_FILE_TOO_BIG_ERROR, 0); + return NULL; +} /* _MD_Unix_mmap64 */ +#endif /* defined(_PR_NO_LARGE_FILES) || defined(SOLARIS2_5) */ + +/* Android <= 19 doesn't have mmap64. */ +#if defined(ANDROID) && __ANDROID_API__ <= 19 +PR_IMPORT(void) *__mmap2(void *, size_t, int, int, int, size_t); + +#define ANDROID_PAGE_SIZE 4096 + +static void * +mmap64(void *addr, size_t len, int prot, int flags, int fd, loff_t offset) +{ + if (offset & (ANDROID_PAGE_SIZE - 1)) { + errno = EINVAL; + return MAP_FAILED; + } + return __mmap2(addr, len, prot, flags, fd, offset / ANDROID_PAGE_SIZE); +} +#endif + +#if defined(OSF1) && defined(__GNUC__) + +/* + * On OSF1 V5.0A, <sys/stat.h> defines stat and fstat as + * macros when compiled under gcc, so it is rather tricky to + * take the addresses of the real functions the macros expend + * to. A simple solution is to define forwarder functions + * and take the addresses of the forwarder functions instead. + */ + +static int stat_forwarder(const char *path, struct stat *buffer) +{ + return stat(path, buffer); +} + +static int fstat_forwarder(int filedes, struct stat *buffer) +{ + return fstat(filedes, buffer); +} + +#endif + +static void _PR_InitIOV(void) +{ +#if defined(SOLARIS2_5) + PRLibrary *lib; + void *open64_func; + + open64_func = PR_FindSymbolAndLibrary("open64", &lib); + if (NULL != open64_func) + { + PR_ASSERT(NULL != lib); + _md_iovector._open64 = (_MD_Open64)open64_func; + _md_iovector._mmap64 = (_MD_Mmap64)PR_FindSymbol(lib, "mmap64"); + _md_iovector._fstat64 = (_MD_Fstat64)PR_FindSymbol(lib, "fstat64"); + _md_iovector._stat64 = (_MD_Stat64)PR_FindSymbol(lib, "stat64"); + _md_iovector._lseek64 = (_MD_Lseek64)PR_FindSymbol(lib, "lseek64"); + (void)PR_UnloadLibrary(lib); + } + else + { + _md_iovector._open64 = open; + _md_iovector._mmap64 = _MD_Unix_mmap64; + _md_iovector._fstat64 = _MD_solaris25_fstat64; + _md_iovector._stat64 = _MD_solaris25_stat64; + _md_iovector._lseek64 = _MD_Unix_lseek64; + } +#elif defined(_PR_NO_LARGE_FILES) + _md_iovector._open64 = open; + _md_iovector._mmap64 = _MD_Unix_mmap64; + _md_iovector._fstat64 = fstat; + _md_iovector._stat64 = stat; + _md_iovector._lseek64 = _MD_Unix_lseek64; +#elif defined(_PR_HAVE_OFF64_T) +#if defined(IRIX5_3) || defined(ANDROID) + /* + * Android doesn't have open64. We pass the O_LARGEFILE flag to open + * in _MD_open. + */ + _md_iovector._open64 = open; +#else + _md_iovector._open64 = open64; +#endif + _md_iovector._mmap64 = mmap64; + _md_iovector._fstat64 = fstat64; + _md_iovector._stat64 = stat64; + _md_iovector._lseek64 = lseek64; +#elif defined(_PR_HAVE_LARGE_OFF_T) + _md_iovector._open64 = open; + _md_iovector._mmap64 = mmap; +#if defined(OSF1) && defined(__GNUC__) + _md_iovector._fstat64 = fstat_forwarder; + _md_iovector._stat64 = stat_forwarder; +#else + _md_iovector._fstat64 = fstat; + _md_iovector._stat64 = stat; +#endif + _md_iovector._lseek64 = lseek; +#else +#error "I don't know yet" +#endif + LL_I2L(minus_one, -1); +} /* _PR_InitIOV */ + +void _PR_UnixInit(void) +{ + struct sigaction sigact; + int rv; + + sigemptyset(&timer_set); + +#if !defined(_PR_PTHREADS) + + sigaddset(&timer_set, SIGALRM); + sigemptyset(&empty_set); + intr_timeout_ticks = + PR_SecondsToInterval(_PR_INTERRUPT_CHECK_INTERVAL_SECS); + +#if defined(SOLARIS) || defined(IRIX) + + if (getenv("NSPR_SIGSEGV_HANDLE")) { + sigact.sa_handler = sigsegvhandler; + sigact.sa_flags = 0; + sigact.sa_mask = timer_set; + sigaction(SIGSEGV, &sigact, 0); + } + + if (getenv("NSPR_SIGABRT_HANDLE")) { + sigact.sa_handler = sigaborthandler; + sigact.sa_flags = 0; + sigact.sa_mask = timer_set; + sigaction(SIGABRT, &sigact, 0); + } + + if (getenv("NSPR_SIGBUS_HANDLE")) { + sigact.sa_handler = sigbushandler; + sigact.sa_flags = 0; + sigact.sa_mask = timer_set; + sigaction(SIGBUS, &sigact, 0); + } + +#endif +#endif /* !defined(_PR_PTHREADS) */ + + /* + * Under HP-UX DCE threads, sigaction() installs a per-thread + * handler, so we use sigvector() to install a process-wide + * handler. + */ +#if defined(HPUX) && defined(_PR_DCETHREADS) + { + struct sigvec vec; + + vec.sv_handler = SIG_IGN; + vec.sv_mask = 0; + vec.sv_flags = 0; + rv = sigvector(SIGPIPE, &vec, NULL); + PR_ASSERT(0 == rv); + } +#else + sigact.sa_handler = SIG_IGN; + sigemptyset(&sigact.sa_mask); + sigact.sa_flags = 0; + rv = sigaction(SIGPIPE, &sigact, 0); + PR_ASSERT(0 == rv); +#endif /* HPUX && _PR_DCETHREADS */ + + _pr_rename_lock = PR_NewLock(); + PR_ASSERT(NULL != _pr_rename_lock); + _pr_Xfe_mon = PR_NewMonitor(); + PR_ASSERT(NULL != _pr_Xfe_mon); + + _PR_InitIOV(); /* one last hack */ +} + +void _PR_UnixCleanup(void) +{ + if (_pr_rename_lock) { + PR_DestroyLock(_pr_rename_lock); + _pr_rename_lock = NULL; + } + if (_pr_Xfe_mon) { + PR_DestroyMonitor(_pr_Xfe_mon); + _pr_Xfe_mon = NULL; + } +} + +#if !defined(_PR_PTHREADS) + +/* + * Variables used by the GC code, initialized in _MD_InitSegs(). + */ +static PRInt32 _pr_zero_fd = -1; +static PRLock *_pr_md_lock = NULL; + +/* + * _MD_InitSegs -- + * + * This is Unix's version of _PR_MD_INIT_SEGS(), which is + * called by _PR_InitSegs(), which in turn is called by + * PR_Init(). + */ +void _MD_InitSegs(void) +{ +#ifdef DEBUG + /* + ** Disable using mmap(2) if NSPR_NO_MMAP is set + */ + if (getenv("NSPR_NO_MMAP")) { + _pr_zero_fd = -2; + return; + } +#endif + _pr_zero_fd = open("/dev/zero",O_RDWR , 0); + /* Prevent the fd from being inherited by child processes */ + fcntl(_pr_zero_fd, F_SETFD, FD_CLOEXEC); + _pr_md_lock = PR_NewLock(); +} + +PRStatus _MD_AllocSegment(PRSegment *seg, PRUint32 size, void *vaddr) +{ + static char *lastaddr = (char*) _PR_STACK_VMBASE; + PRStatus retval = PR_SUCCESS; + int prot; + void *rv; + + PR_ASSERT(seg != 0); + PR_ASSERT(size != 0); + + PR_Lock(_pr_md_lock); + if (_pr_zero_fd < 0) { +from_heap: + seg->vaddr = PR_MALLOC(size); + if (!seg->vaddr) { + retval = PR_FAILURE; + } + else { + seg->size = size; + } + goto exit; + } + + prot = PROT_READ|PROT_WRITE; + /* + * On Alpha Linux, the user-level thread stack needs + * to be made executable because longjmp/signal seem + * to put machine instructions on the stack. + */ +#if defined(LINUX) && defined(__alpha) + prot |= PROT_EXEC; +#endif + rv = mmap((vaddr != 0) ? vaddr : lastaddr, size, prot, + _MD_MMAP_FLAGS, + _pr_zero_fd, 0); + if (rv == (void*)-1) { + goto from_heap; + } + lastaddr += size; + seg->vaddr = rv; + seg->size = size; + seg->flags = _PR_SEG_VM; + +exit: + PR_Unlock(_pr_md_lock); + return retval; +} + +void _MD_FreeSegment(PRSegment *seg) +{ + if (seg->flags & _PR_SEG_VM) + (void) munmap(seg->vaddr, seg->size); + else + PR_DELETE(seg->vaddr); +} + +#endif /* _PR_PTHREADS */ + +/* + *----------------------------------------------------------------------- + * + * PR_Now -- + * + * Returns the current time in microseconds since the epoch. + * The epoch is midnight January 1, 1970 GMT. + * The implementation is machine dependent. This is the Unix + * implementation. + * Cf. time_t time(time_t *tp) + * + *----------------------------------------------------------------------- + */ + +PR_IMPLEMENT(PRTime) +PR_Now(void) +{ + struct timeval tv; + PRInt64 s, us, s2us; + + GETTIMEOFDAY(&tv); + LL_I2L(s2us, PR_USEC_PER_SEC); + LL_I2L(s, tv.tv_sec); + LL_I2L(us, tv.tv_usec); + LL_MUL(s, s, s2us); + LL_ADD(s, s, us); + return s; +} + +#if defined(_MD_INTERVAL_USE_GTOD) +/* + * This version of interval times is based on the time of day + * capability offered by the system. This isn't valid for two reasons: + * 1) The time of day is neither linear nor montonically increasing + * 2) The units here are milliseconds. That's not appropriate for our use. + */ +PRIntervalTime _PR_UNIX_GetInterval() +{ + struct timeval time; + PRIntervalTime ticks; + + (void)GETTIMEOFDAY(&time); /* fallicy of course */ + ticks = (PRUint32)time.tv_sec * PR_MSEC_PER_SEC; /* that's in milliseconds */ + ticks += (PRUint32)time.tv_usec / PR_USEC_PER_MSEC; /* so's that */ + return ticks; +} /* _PR_UNIX_GetInterval */ + +PRIntervalTime _PR_UNIX_TicksPerSecond() +{ + return 1000; /* this needs some work :) */ +} +#endif + +#if defined(_PR_HAVE_CLOCK_MONOTONIC) +PRIntervalTime _PR_UNIX_GetInterval2() +{ + struct timespec time; + PRIntervalTime ticks; + + if (clock_gettime(CLOCK_MONOTONIC, &time) != 0) { + fprintf(stderr, "clock_gettime failed: %d\n", errno); + abort(); + } + + ticks = (PRUint32)time.tv_sec * PR_MSEC_PER_SEC; + ticks += (PRUint32)time.tv_nsec / PR_NSEC_PER_MSEC; + return ticks; +} + +PRIntervalTime _PR_UNIX_TicksPerSecond2() +{ + return 1000; +} +#endif + +#if !defined(_PR_PTHREADS) +/* + * Wait for I/O on multiple descriptors. + * + * Return 0 if timed out, return -1 if interrupted, + * else return the number of ready descriptors. + */ +PRInt32 _PR_WaitForMultipleFDs( + _PRUnixPollDesc *unixpds, + PRInt32 pdcnt, + PRIntervalTime timeout) +{ + PRPollQueue pq; + PRIntn is; + PRInt32 rv; + _PRCPU *io_cpu; + _PRUnixPollDesc *unixpd, *eunixpd; + PRThread *me = _PR_MD_CURRENT_THREAD(); + + PR_ASSERT(!(me->flags & _PR_IDLE_THREAD)); + + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + return -1; + } + + pq.pds = unixpds; + pq.npds = pdcnt; + + _PR_INTSOFF(is); + _PR_MD_IOQ_LOCK(); + _PR_THREAD_LOCK(me); + + pq.thr = me; + io_cpu = me->cpu; + pq.on_ioq = PR_TRUE; + pq.timeout = timeout; + _PR_ADD_TO_IOQ(pq, me->cpu); + +#if !defined(_PR_USE_POLL) + eunixpd = unixpds + pdcnt; + for (unixpd = unixpds; unixpd < eunixpd; unixpd++) { + PRInt32 osfd = unixpd->osfd; + if (unixpd->in_flags & _PR_UNIX_POLL_READ) { + FD_SET(osfd, &_PR_FD_READ_SET(me->cpu)); + _PR_FD_READ_CNT(me->cpu)[osfd]++; + } + if (unixpd->in_flags & _PR_UNIX_POLL_WRITE) { + FD_SET(osfd, &_PR_FD_WRITE_SET(me->cpu)); + (_PR_FD_WRITE_CNT(me->cpu))[osfd]++; + } + if (unixpd->in_flags & _PR_UNIX_POLL_EXCEPT) { + FD_SET(osfd, &_PR_FD_EXCEPTION_SET(me->cpu)); + (_PR_FD_EXCEPTION_CNT(me->cpu))[osfd]++; + } + if (osfd > _PR_IOQ_MAX_OSFD(me->cpu)) { + _PR_IOQ_MAX_OSFD(me->cpu) = osfd; + } + } +#endif /* !defined(_PR_USE_POLL) */ + + if (_PR_IOQ_TIMEOUT(me->cpu) > timeout) { + _PR_IOQ_TIMEOUT(me->cpu) = timeout; + } + + _PR_IOQ_OSFD_CNT(me->cpu) += pdcnt; + + _PR_SLEEPQ_LOCK(me->cpu); + _PR_ADD_SLEEPQ(me, timeout); + me->state = _PR_IO_WAIT; + me->io_pending = PR_TRUE; + me->io_suspended = PR_FALSE; + _PR_SLEEPQ_UNLOCK(me->cpu); + _PR_THREAD_UNLOCK(me); + _PR_MD_IOQ_UNLOCK(); + + _PR_MD_WAIT(me, timeout); + + me->io_pending = PR_FALSE; + me->io_suspended = PR_FALSE; + + /* + * This thread should run on the same cpu on which it was blocked; when + * the IO request times out the fd sets and fd counts for the + * cpu are updated below. + */ + PR_ASSERT(me->cpu == io_cpu); + + /* + ** If we timed out the pollq might still be on the ioq. Remove it + ** before continuing. + */ + if (pq.on_ioq) { + _PR_MD_IOQ_LOCK(); + /* + * Need to check pq.on_ioq again + */ + if (pq.on_ioq) { + PR_REMOVE_LINK(&pq.links); +#ifndef _PR_USE_POLL + eunixpd = unixpds + pdcnt; + for (unixpd = unixpds; unixpd < eunixpd; unixpd++) { + PRInt32 osfd = unixpd->osfd; + PRInt16 in_flags = unixpd->in_flags; + + if (in_flags & _PR_UNIX_POLL_READ) { + if (--(_PR_FD_READ_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_READ_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_WRITE) { + if (--(_PR_FD_WRITE_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_WRITE_SET(me->cpu)); + } + if (in_flags & _PR_UNIX_POLL_EXCEPT) { + if (--(_PR_FD_EXCEPTION_CNT(me->cpu))[osfd] == 0) + FD_CLR(osfd, &_PR_FD_EXCEPTION_SET(me->cpu)); + } + } +#endif /* _PR_USE_POLL */ + PR_ASSERT(pq.npds == pdcnt); + _PR_IOQ_OSFD_CNT(me->cpu) -= pdcnt; + PR_ASSERT(_PR_IOQ_OSFD_CNT(me->cpu) >= 0); + } + _PR_MD_IOQ_UNLOCK(); + } + /* XXX Should we use _PR_FAST_INTSON or _PR_INTSON? */ + if (1 == pdcnt) { + _PR_FAST_INTSON(is); + } else { + _PR_INTSON(is); + } + + if (_PR_PENDING_INTERRUPT(me)) { + me->flags &= ~_PR_INTERRUPT; + PR_SetError(PR_PENDING_INTERRUPT_ERROR, 0); + return -1; + } + + rv = 0; + if (pq.on_ioq == PR_FALSE) { + /* Count the number of ready descriptors */ + while (--pdcnt >= 0) { + if (unixpds->out_flags != 0) { + rv++; + } + unixpds++; + } + } + + return rv; +} + +/* + * Unblock threads waiting for I/O + * used when interrupting threads + * + * NOTE: The thread lock should held when this function is called. + * On return, the thread lock is released. + */ +void _PR_Unblock_IO_Wait(PRThread *thr) +{ + int pri = thr->priority; + _PRCPU *cpu = thr->cpu; + + /* + * GLOBAL threads wakeup periodically to check for interrupt + */ + if (_PR_IS_NATIVE_THREAD(thr)) { + _PR_THREAD_UNLOCK(thr); + return; + } + + PR_ASSERT(thr->flags & (_PR_ON_SLEEPQ | _PR_ON_PAUSEQ)); + _PR_SLEEPQ_LOCK(cpu); + _PR_DEL_SLEEPQ(thr, PR_TRUE); + _PR_SLEEPQ_UNLOCK(cpu); + + PR_ASSERT(!(thr->flags & _PR_IDLE_THREAD)); + thr->state = _PR_RUNNABLE; + _PR_RUNQ_LOCK(cpu); + _PR_ADD_RUNQ(thr, cpu, pri); + _PR_RUNQ_UNLOCK(cpu); + _PR_THREAD_UNLOCK(thr); + _PR_MD_WAKEUP_WAITER(thr); +} +#endif /* !defined(_PR_PTHREADS) */ + +/* + * When a nonblocking connect has completed, determine whether it + * succeeded or failed, and if it failed, what the error code is. + * + * The function returns the error code. An error code of 0 means + * that the nonblocking connect succeeded. + */ + +int _MD_unix_get_nonblocking_connect_error(int osfd) +{ +#if defined(NTO) + /* Neutrino does not support the SO_ERROR socket option */ + PRInt32 rv; + PRNetAddr addr; + _PRSockLen_t addrlen = sizeof(addr); + + /* Test to see if we are using the Tiny TCP/IP Stack or the Full one. */ + struct statvfs superblock; + rv = fstatvfs(osfd, &superblock); + if (rv == 0) { + if (strcmp(superblock.f_basetype, "ttcpip") == 0) { + /* Using the Tiny Stack! */ + rv = getpeername(osfd, (struct sockaddr *) &addr, + (_PRSockLen_t *) &addrlen); + if (rv == -1) { + int errno_copy = errno; /* make a copy so I don't + * accidentally reset */ + + if (errno_copy == ENOTCONN) { + struct stat StatInfo; + rv = fstat(osfd, &StatInfo); + if (rv == 0) { + time_t current_time = time(NULL); + + /* + * this is a real hack, can't explain why it + * works it just does + */ + if (abs(current_time - StatInfo.st_atime) < 5) { + return ECONNREFUSED; + } else { + return ETIMEDOUT; + } + } else { + return ECONNREFUSED; + } + } else { + return errno_copy; + } + } else { + /* No Error */ + return 0; + } + } else { + /* Have the FULL Stack which supports SO_ERROR */ + /* Hasn't been written yet, never been tested! */ + /* Jerry.Kirk@Nexwarecorp.com */ + + int err; + _PRSockLen_t optlen = sizeof(err); + + if (getsockopt(osfd, SOL_SOCKET, SO_ERROR, + (char *) &err, &optlen) == -1) { + return errno; + } else { + return err; + } + } + } else { + return ECONNREFUSED; + } +#elif defined(UNIXWARE) + /* + * getsockopt() fails with EPIPE, so use getmsg() instead. + */ + + int rv; + int flags = 0; + rv = getmsg(osfd, NULL, NULL, &flags); + PR_ASSERT(-1 == rv || 0 == rv); + if (-1 == rv && errno != EAGAIN && errno != EWOULDBLOCK) { + return errno; + } + return 0; /* no error */ +#else + int err; + _PRSockLen_t optlen = sizeof(err); + if (getsockopt(osfd, SOL_SOCKET, SO_ERROR, (char *) &err, &optlen) == -1) { + return errno; + } else { + return err; + } +#endif +} + +/************************************************************************/ + +/* +** Special hacks for xlib. Xlib/Xt/Xm is not re-entrant nor is it thread +** safe. Unfortunately, neither is mozilla. To make these programs work +** in a pre-emptive threaded environment, we need to use a lock. +*/ + +void PR_XLock(void) +{ + PR_EnterMonitor(_pr_Xfe_mon); +} + +void PR_XUnlock(void) +{ + PR_ExitMonitor(_pr_Xfe_mon); +} + +PRBool PR_XIsLocked(void) +{ + return (PR_InMonitor(_pr_Xfe_mon)) ? PR_TRUE : PR_FALSE; +} + +void PR_XWait(int ms) +{ + PR_Wait(_pr_Xfe_mon, PR_MillisecondsToInterval(ms)); +} + +void PR_XNotify(void) +{ + PR_Notify(_pr_Xfe_mon); +} + +void PR_XNotifyAll(void) +{ + PR_NotifyAll(_pr_Xfe_mon); +} + +#if defined(HAVE_FCNTL_FILE_LOCKING) + +PRStatus +_MD_LockFile(PRInt32 f) +{ + PRInt32 rv; + struct flock arg; + + arg.l_type = F_WRLCK; + arg.l_whence = SEEK_SET; + arg.l_start = 0; + arg.l_len = 0; /* until EOF */ + rv = fcntl(f, F_SETLKW, &arg); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_TLockFile(PRInt32 f) +{ + PRInt32 rv; + struct flock arg; + + arg.l_type = F_WRLCK; + arg.l_whence = SEEK_SET; + arg.l_start = 0; + arg.l_len = 0; /* until EOF */ + rv = fcntl(f, F_SETLK, &arg); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_UnlockFile(PRInt32 f) +{ + PRInt32 rv; + struct flock arg; + + arg.l_type = F_UNLCK; + arg.l_whence = SEEK_SET; + arg.l_start = 0; + arg.l_len = 0; /* until EOF */ + rv = fcntl(f, F_SETLK, &arg); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +#elif defined(HAVE_BSD_FLOCK) + +#include <sys/file.h> + +PRStatus +_MD_LockFile(PRInt32 f) +{ + PRInt32 rv; + rv = flock(f, LOCK_EX); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_TLockFile(PRInt32 f) +{ + PRInt32 rv; + rv = flock(f, LOCK_EX|LOCK_NB); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_UnlockFile(PRInt32 f) +{ + PRInt32 rv; + rv = flock(f, LOCK_UN); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_FLOCK_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} +#else + +PRStatus +_MD_LockFile(PRInt32 f) +{ + PRInt32 rv; + rv = lockf(f, F_LOCK, 0); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_LOCKF_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_TLockFile(PRInt32 f) +{ + PRInt32 rv; + rv = lockf(f, F_TLOCK, 0); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_LOCKF_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus +_MD_UnlockFile(PRInt32 f) +{ + PRInt32 rv; + rv = lockf(f, F_ULOCK, 0); + if (rv == 0) + return PR_SUCCESS; + _PR_MD_MAP_LOCKF_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} +#endif + +PRStatus _MD_gethostname(char *name, PRUint32 namelen) +{ + PRIntn rv; + + rv = gethostname(name, namelen); + if (0 == rv) { + return PR_SUCCESS; + } + _PR_MD_MAP_GETHOSTNAME_ERROR(_MD_ERRNO()); + return PR_FAILURE; +} + +PRStatus _MD_getsysinfo(PRSysInfo cmd, char *name, PRUint32 namelen) +{ + struct utsname info; + + PR_ASSERT((cmd == PR_SI_SYSNAME) || (cmd == PR_SI_RELEASE)); + + if (uname(&info) == -1) { + _PR_MD_MAP_DEFAULT_ERROR(errno); + return PR_FAILURE; + } + if (PR_SI_SYSNAME == cmd) + (void)PR_snprintf(name, namelen, info.sysname); + else if (PR_SI_RELEASE == cmd) + (void)PR_snprintf(name, namelen, info.release); + else + return PR_FAILURE; + return PR_SUCCESS; +} + +/* + ******************************************************************* + * + * Memory-mapped files + * + ******************************************************************* + */ + +PRStatus _MD_CreateFileMap(PRFileMap *fmap, PRInt64 size) +{ + PRFileInfo info; + PRUint32 sz; + + LL_L2UI(sz, size); + if (sz) { + if (PR_GetOpenFileInfo(fmap->fd, &info) == PR_FAILURE) { + return PR_FAILURE; + } + if (sz > info.size) { + /* + * Need to extend the file + */ + if (fmap->prot != PR_PROT_READWRITE) { + PR_SetError(PR_NO_ACCESS_RIGHTS_ERROR, 0); + return PR_FAILURE; + } + if (PR_Seek(fmap->fd, sz - 1, PR_SEEK_SET) == -1) { + return PR_FAILURE; + } + if (PR_Write(fmap->fd, "", 1) != 1) { + return PR_FAILURE; + } + } + } + if (fmap->prot == PR_PROT_READONLY) { + fmap->md.prot = PROT_READ; +#ifdef OSF1V4_MAP_PRIVATE_BUG + /* + * Use MAP_SHARED to work around a bug in OSF1 V4.0D + * (QAR 70220 in the OSF_QAR database) that results in + * corrupted data in the memory-mapped region. This + * bug is fixed in V5.0. + */ + fmap->md.flags = MAP_SHARED; +#else + fmap->md.flags = MAP_PRIVATE; +#endif + } else if (fmap->prot == PR_PROT_READWRITE) { + fmap->md.prot = PROT_READ | PROT_WRITE; + fmap->md.flags = MAP_SHARED; + } else { + PR_ASSERT(fmap->prot == PR_PROT_WRITECOPY); + fmap->md.prot = PROT_READ | PROT_WRITE; + fmap->md.flags = MAP_PRIVATE; + } + return PR_SUCCESS; +} + +void * _MD_MemMap( + PRFileMap *fmap, + PRInt64 offset, + PRUint32 len) +{ + PRInt32 off; + void *addr; + + LL_L2I(off, offset); + if ((addr = mmap(0, len, fmap->md.prot, fmap->md.flags, + fmap->fd->secret->md.osfd, off)) == (void *) -1) { + _PR_MD_MAP_MMAP_ERROR(_MD_ERRNO()); + addr = NULL; + } + return addr; +} + +PRStatus _MD_MemUnmap(void *addr, PRUint32 len) +{ + if (munmap(addr, len) == 0) { + return PR_SUCCESS; + } + _PR_MD_MAP_DEFAULT_ERROR(errno); + return PR_FAILURE; +} + +PRStatus _MD_CloseFileMap(PRFileMap *fmap) +{ + if ( PR_TRUE == fmap->md.isAnonFM ) { + PRStatus rc = PR_Close( fmap->fd ); + if ( PR_FAILURE == rc ) { + PR_LOG( _pr_io_lm, PR_LOG_DEBUG, + ("_MD_CloseFileMap(): error closing anonymnous file map osfd")); + return PR_FAILURE; + } + } + PR_DELETE(fmap); + return PR_SUCCESS; +} + +PRStatus _MD_SyncMemMap( + PRFileDesc *fd, + void *addr, + PRUint32 len) +{ + /* msync(..., MS_SYNC) alone is sufficient to flush modified data to disk + * synchronously. It is not necessary to call fsync. */ + if (msync(addr, len, MS_SYNC) == 0) { + return PR_SUCCESS; + } + _PR_MD_MAP_DEFAULT_ERROR(errno); + return PR_FAILURE; +} + +#if defined(_PR_NEED_FAKE_POLL) + +/* + * Some platforms don't have poll(). For easier porting of code + * that calls poll(), we emulate poll() using select(). + */ + +int poll(struct pollfd *filedes, unsigned long nfds, int timeout) +{ + int i; + int rv; + int maxfd; + fd_set rd, wr, ex; + struct timeval tv, *tvp; + + if (timeout < 0 && timeout != -1) { + errno = EINVAL; + return -1; + } + + if (timeout == -1) { + tvp = NULL; + } else { + tv.tv_sec = timeout / 1000; + tv.tv_usec = (timeout % 1000) * 1000; + tvp = &tv; + } + + maxfd = -1; + FD_ZERO(&rd); + FD_ZERO(&wr); + FD_ZERO(&ex); + + for (i = 0; i < nfds; i++) { + int osfd = filedes[i].fd; + int events = filedes[i].events; + PRBool fdHasEvent = PR_FALSE; + + if (osfd < 0) { + continue; /* Skip this osfd. */ + } + + /* + * Map the poll events to the select fd_sets. + * POLLIN, POLLRDNORM ===> readable + * POLLOUT, POLLWRNORM ===> writable + * POLLPRI, POLLRDBAND ===> exception + * POLLNORM, POLLWRBAND (and POLLMSG on some platforms) + * are ignored. + * + * The output events POLLERR and POLLHUP are never turned on. + * POLLNVAL may be turned on. + */ + + if (events & (POLLIN | POLLRDNORM)) { + FD_SET(osfd, &rd); + fdHasEvent = PR_TRUE; + } + if (events & (POLLOUT | POLLWRNORM)) { + FD_SET(osfd, &wr); + fdHasEvent = PR_TRUE; + } + if (events & (POLLPRI | POLLRDBAND)) { + FD_SET(osfd, &ex); + fdHasEvent = PR_TRUE; + } + if (fdHasEvent && osfd > maxfd) { + maxfd = osfd; + } + } + + rv = select(maxfd + 1, &rd, &wr, &ex, tvp); + + /* Compute poll results */ + if (rv > 0) { + rv = 0; + for (i = 0; i < nfds; i++) { + PRBool fdHasEvent = PR_FALSE; + + filedes[i].revents = 0; + if (filedes[i].fd < 0) { + continue; + } + if (FD_ISSET(filedes[i].fd, &rd)) { + if (filedes[i].events & POLLIN) { + filedes[i].revents |= POLLIN; + } + if (filedes[i].events & POLLRDNORM) { + filedes[i].revents |= POLLRDNORM; + } + fdHasEvent = PR_TRUE; + } + if (FD_ISSET(filedes[i].fd, &wr)) { + if (filedes[i].events & POLLOUT) { + filedes[i].revents |= POLLOUT; + } + if (filedes[i].events & POLLWRNORM) { + filedes[i].revents |= POLLWRNORM; + } + fdHasEvent = PR_TRUE; + } + if (FD_ISSET(filedes[i].fd, &ex)) { + if (filedes[i].events & POLLPRI) { + filedes[i].revents |= POLLPRI; + } + if (filedes[i].events & POLLRDBAND) { + filedes[i].revents |= POLLRDBAND; + } + fdHasEvent = PR_TRUE; + } + if (fdHasEvent) { + rv++; + } + } + PR_ASSERT(rv > 0); + } else if (rv == -1 && errno == EBADF) { + rv = 0; + for (i = 0; i < nfds; i++) { + filedes[i].revents = 0; + if (filedes[i].fd < 0) { + continue; + } + if (fcntl(filedes[i].fd, F_GETFL, 0) == -1) { + filedes[i].revents = POLLNVAL; + rv++; + } + } + PR_ASSERT(rv > 0); + } + PR_ASSERT(-1 != timeout || rv != 0); + + return rv; +} +#endif /* _PR_NEED_FAKE_POLL */ |