minix/servers/vfs/select.c

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/* Implement entry point to select system call.
*
* The entry points into this file are
* do_select: perform the SELECT system call
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* select_callback: notify select system of possible fd operation
endpoint-aware conversion of servers. 'who', indicating caller number in pm and fs and some other servers, has been removed in favour of 'who_e' (endpoint) and 'who_p' (proc nr.). In both PM and FS, isokendpt() convert endpoints to process slot numbers, returning OK if it was a valid and consistent endpoint number. okendpt() does the same but panic()s if it doesn't succeed. (In PM, this is pm_isok..) pm and fs keep their own records of process endpoints in their proc tables, which are needed to make kernel calls about those processes. message field names have changed. fs drivers are endpoints. fs now doesn't try to get out of driver deadlock, as the protocol isn't supposed to let that happen any more. (A warning is printed if ELOCKED is detected though.) fproc[].fp_task (indicating which driver the process is suspended on) became an int. PM and FS now get endpoint numbers of initial boot processes from the kernel. These happen to be the same as the old proc numbers, to let user processes reach them with the old numbers, but FS and PM don't know that. All new processes after INIT, even after the generation number wraps around, get endpoint numbers with generation 1 and higher, so the first instances of the boot processes are the only processes ever to have endpoint numbers in the old proc number range. More return code checks of sys_* functions have been added. IS has become endpoint-aware. Ditched the 'text' and 'data' fields in the kernel dump (which show locations, not sizes, so aren't terribly useful) in favour of the endpoint number. Proc number is still visible. Some other dumps (e.g. dmap, rs) show endpoint numbers now too which got the formatting changed. PM reading segments using rw_seg() has changed - it uses other fields in the message now instead of encoding the segment and process number and fd in the fd field. For that it uses _read_pm() and _write_pm() which to _taskcall()s directly in pm/misc.c. PM now sys_exit()s itself on panic(), instead of sys_abort(). RS also talks in endpoints instead of process numbers.
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* select_unsuspend_by_endpt: cancel a blocking select on exiting driver
*/
#include "fs.h"
#include <sys/fcntl.h>
#include <sys/time.h>
#include <sys/select.h>
#include <sys/stat.h>
#include <minix/com.h>
#include <minix/u64.h>
#include <string.h>
#include <assert.h>
#include "file.h"
#include "fproc.h"
#include "dmap.h"
#include "vnode.h"
/* max. number of simultaneously pending select() calls */
#define MAXSELECTS 25
#define FROM_PROC 0
#define TO_PROC 1
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static struct selectentry {
struct fproc *requestor; /* slot is free iff this is NULL */
endpoint_t req_endpt;
fd_set readfds, writefds, errorfds;
fd_set ready_readfds, ready_writefds, ready_errorfds;
fd_set *vir_readfds, *vir_writefds, *vir_errorfds;
struct filp *filps[OPEN_MAX];
int type[OPEN_MAX];
int nfds, nreadyfds;
int error;
char block;
clock_t expiry;
timer_t timer; /* if expiry > 0 */
} selecttab[MAXSELECTS];
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static int copy_fdsets(struct selectentry *se, int nfds, int
direction);
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static int do_select_request(struct selectentry *se, int fd, int *ops);
static void filp_status(struct filp *fp, int status);
static int is_deferred(struct selectentry *se);
static void restart_proc(struct selectentry *se);
static void ops2tab(int ops, int fd, struct selectentry *e);
static int is_regular_file(struct filp *f);
static int is_pipe(struct filp *f);
static int is_supported_major(struct filp *f);
static void select_lock_filp(struct filp *f, int ops);
static int select_request_async(struct filp *f, int *ops, int block);
static int select_request_file(struct filp *f, int *ops, int block);
static int select_request_major(struct filp *f, int *ops, int block);
static int select_request_pipe(struct filp *f, int *ops, int block);
static int select_request_sync(struct filp *f, int *ops, int block);
static void select_cancel_all(struct selectentry *e);
static void select_cancel_filp(struct filp *f);
static void select_return(struct selectentry *);
static void select_restart_filps(void);
static int tab2ops(int fd, struct selectentry *e);
static void wipe_select(struct selectentry *s);
static struct fdtype {
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int (*select_request)(struct filp *, int *ops, int block);
int (*type_match)(struct filp *f);
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} fdtypes[] = {
{ select_request_major, is_supported_major },
{ select_request_file, is_regular_file },
{ select_request_pipe, is_pipe },
};
#define SEL_FDS (sizeof(fdtypes) / sizeof(fdtypes[0]))
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static int select_majors[] = { /* List of majors that support selecting on */
TTY_MAJOR,
INET_MAJOR,
UDS_MAJOR,
LOG_MAJOR,
};
#define SEL_MAJORS (sizeof(select_majors) / sizeof(select_majors[0]))
/*===========================================================================*
* do_select *
*===========================================================================*/
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int do_select(void)
{
/* Implement the select(nfds, readfds, writefds, errorfds, timeout) system
* call. First we copy the arguments and verify their sanity. Then we check
* whether there are file descriptors that satisfy the select call right of the
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* bat. If so, or if there are no ready file descriptors but the process
* requested to return immediately, we return the result. Otherwise we set a
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* timeout and wait for either the file descriptors to become ready or the
* timer to go off. If no timeout value was provided, we wait indefinitely. */
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int r, nfds, do_timeout = 0, fd, s;
struct timeval timeout;
struct selectentry *se;
vir_bytes vtimeout;
nfds = job_m_in.SEL_NFDS;
vtimeout = (vir_bytes) job_m_in.SEL_TIMEOUT;
/* Sane amount of file descriptors? */
if (nfds < 0 || nfds > OPEN_MAX) return(EINVAL);
/* Find a slot to store this select request */
for (s = 0; s < MAXSELECTS; s++)
if (selecttab[s].requestor == NULL) /* Unused slot */
break;
if (s >= MAXSELECTS) return(ENOSPC);
se = &selecttab[s];
wipe_select(se); /* Clear results of previous usage */
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
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se->requestor = fp;
se->req_endpt = who_e;
se->vir_readfds = (fd_set *) job_m_in.SEL_READFDS;
se->vir_writefds = (fd_set *) job_m_in.SEL_WRITEFDS;
se->vir_errorfds = (fd_set *) job_m_in.SEL_ERRORFDS;
/* Copy fdsets from the process */
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
if ((r = copy_fdsets(se, nfds, FROM_PROC)) != OK) {
se->requestor = NULL;
return(r);
}
/* Did the process set a timeout value? If so, retrieve it. */
if (vtimeout != 0) {
2012-02-13 16:28:04 +01:00
do_timeout = 1;
r = sys_vircopy(who_e, (vir_bytes) vtimeout, SELF,
(vir_bytes) &timeout, sizeof(timeout));
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
if (r != OK) {
se->requestor = NULL;
return(r);
}
}
/* No nonsense in the timeval */
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
if (do_timeout && (timeout.tv_sec < 0 || timeout.tv_usec < 0)) {
se->requestor = NULL;
return(EINVAL);
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
}
/* If there is no timeout, we block forever. Otherwise, we block up to the
2012-02-13 16:28:04 +01:00
* specified time interval.
*/
if (!do_timeout) /* No timeout value set */
se->block = 1;
else if (do_timeout && (timeout.tv_sec > 0 || timeout.tv_usec > 0))
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se->block = 1;
else /* timeout set as (0,0) - this effects a poll */
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se->block = 0;
se->expiry = 0; /* no timer set (yet) */
/* Verify that file descriptors are okay to select on */
for (fd = 0; fd < nfds; fd++) {
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struct filp *f;
unsigned int type, ops;
/* Because the select() interface implicitly includes file descriptors
* you might not want to select on, we have to figure out whether we're
* interested in them. Typically, these file descriptors include fd's
* inherited from the parent proc and file descriptors that have been
* close()d, but had a lower fd than one in the current set.
*/
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if (!(ops = tab2ops(fd, se)))
continue; /* No operations set; nothing to do for this fd */
/* Get filp belonging to this fd */
2012-02-13 16:28:04 +01:00
f = se->filps[fd] = get_filp(fd, VNODE_READ);
if (f == NULL) {
2012-02-13 16:28:04 +01:00
if (err_code == EBADF)
r = err_code;
else /* File descriptor is 'ready' to return EIO */
r = EINTR;
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
se->requestor = NULL;
return(r);
2012-02-13 16:28:04 +01:00
}
/* Check file types. According to POSIX 2008:
* "The pselect() and select() functions shall support regular files,
* terminal and pseudo-terminal devices, FIFOs, pipes, and sockets. The
* behavior of pselect() and select() on file descriptors that refer to
* other types of file is unspecified."
*
* In our case, terminal and pseudo-terminal devices are handled by the
* TTY major and sockets by either INET major (socket type AF_INET) or
* PFS major (socket type AF_UNIX). PFS acts as an FS when it handles
* pipes and as a driver when it handles sockets. Additionally, we
* support select on the LOG major to handle kernel logging, which is
* beyond the POSIX spec. */
se->type[fd] = -1;
for (type = 0; type < SEL_FDS; type++) {
if (fdtypes[type].type_match(f)) {
se->type[fd] = type;
se->nfds = fd+1;
se->filps[fd]->filp_selectors++;
break;
}
}
2012-02-13 16:28:04 +01:00
unlock_filp(f);
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
if (se->type[fd] == -1) { /* Type not found */
se->requestor = NULL;
return(EBADF);
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
}
}
/* Check all file descriptors in the set whether one is 'ready' now */
for (fd = 0; fd < nfds; fd++) {
int ops, r;
struct filp *f;
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/* Again, check for involuntarily selected fd's */
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if (!(ops = tab2ops(fd, se)))
continue; /* No operations set; nothing to do for this fd */
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/* Test filp for select operations if not already done so. e.g.,
* processes sharing a filp and both doing a select on that filp. */
f = se->filps[fd];
if ((f->filp_select_ops & ops) != ops) {
int wantops;
wantops = (f->filp_select_ops |= ops);
r = do_select_request(se, fd, &wantops);
if (r != OK && r != SUSPEND)
break; /* Error or bogus return code; abort */
2012-02-13 16:28:04 +01:00
/* The select request above might have turned on/off some
* operations because they were 'ready' or not meaningful.
* Either way, we might have a result and we need to store them
* in the select table entry. */
if (wantops & ops) ops2tab(wantops, fd, se);
2012-02-13 16:28:04 +01:00
}
}
if ((se->nreadyfds > 0 || !se->block) && !is_deferred(se)) {
/* fd's were found that were ready to go right away, and/or
* we were instructed not to block at all. Must return
* immediately.
*/
r = copy_fdsets(se, se->nfds, TO_PROC);
select_cancel_all(se);
VFS: make all IPC asynchronous By decoupling synchronous drivers from VFS, we are a big step closer to supporting driver crashes under all circumstances. That is, VFS can't become stuck on IPC with a synchronous driver (e.g., INET) and can recover from crashing block drivers during open/close/ioctl or during communication with an FS. In order to maintain serialized communication with a synchronous driver, the communication is wrapped by a mutex on a per driver basis (not major numbers as there can be multiple majors with identical endpoints). Majors that share a driver endpoint point to a single mutex object. In order to support crashes from block drivers, the file reopen tactic had to be changed; first reopen files associated with the crashed driver, then send the new driver endpoint to FSes. This solves a deadlock between the FS and the block driver; - VFS would send REQ_NEW_DRIVER to an FS, but he FS only receives it after retrying the current request to the newly started driver. - The block driver would refuse the retried request until all files had been reopened. - VFS would reopen files only after getting a reply from the initial REQ_NEW_DRIVER. When a character special driver crashes, all associated files have to be marked invalid and closed (or reopened if flagged as such). However, they can only be closed if a thread holds exclusive access to it. To obtain exclusive access, the worker thread (which handles the new driver endpoint event from DS) schedules a new job to garbage collect invalid files. This way, we can signal the worker thread that was talking to the crashed driver and will release exclusive access to a file associated with the crashed driver and prevent the garbage collecting worker thread from dead locking on that file. Also, when a character special driver crashes, RS will unmap the driver and remap it upon restart. During unmapping, associated files are marked invalid instead of waiting for an endpoint up event from DS, as that event might come later than new read/write/select requests and thus cause confusion in the freshly started driver. When locking a filp, the usage counters are no longer checked. The usage counter can legally go down to zero during filp invalidation while there are locks pending. DS events are handled by a separate worker thread instead of the main thread as reopening files could lead to another crash and a stuck thread. An additional worker thread is then necessary to unlock it. Finally, with everything asynchronous a race condition in do_select surfaced. A select entry was only marked in use after succesfully sending initial select requests to drivers and having to wait. When multiple select() calls were handled there was opportunity that these entries were overwritten. This had as effect that some select results were ignored (and select() remained blocking instead if returning) or do_select tried to access filps that were not present (because thrown away by secondary select()). This bug manifested itself with sendrecs, but was very hard to reproduce. However, it became awfully easy to trigger with asynsends only.
2012-08-28 16:06:51 +02:00
se->requestor = NULL;
if (r != OK)
return(r);
else if (se->error != OK)
return(se->error);
return(se->nreadyfds);
}
2012-02-13 16:28:04 +01:00
/* Convert timeval to ticks and set the timer. If it fails, undo
* all, return error.
*/
if (do_timeout) {
int ticks;
/* Open Group:
* "If the requested timeout interval requires a finer
* granularity than the implementation supports, the
* actual timeout interval shall be rounded up to the next
* supported value."
*/
#define USECPERSEC 1000000
while(timeout.tv_usec >= USECPERSEC) {
/* this is to avoid overflow with *system_hz below */
timeout.tv_usec -= USECPERSEC;
timeout.tv_sec++;
}
ticks = timeout.tv_sec * system_hz +
(timeout.tv_usec * system_hz + USECPERSEC-1) / USECPERSEC;
se->expiry = ticks;
2010-07-09 14:58:18 +02:00
set_timer(&se->timer, ticks, select_timeout_check, s);
}
/* process now blocked */
suspend(FP_BLOCKED_ON_SELECT);
return(SUSPEND);
}
/*===========================================================================*
* is_deferred *
*===========================================================================*/
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static int is_deferred(struct selectentry *se)
{
/* Find out whether this select has pending initial replies */
int fd;
struct filp *f;
for (fd = 0; fd < se->nfds; fd++) {
if ((f = se->filps[fd]) == NULL) continue;
if (f->filp_select_flags & (FSF_UPDATE|FSF_BUSY)) return(TRUE);
}
return(FALSE);
}
/*===========================================================================*
* is_regular_file *
*===========================================================================*/
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static int is_regular_file(struct filp *f)
{
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return(f && f->filp_vno && S_ISREG(f->filp_vno->v_mode));
}
/*===========================================================================*
* is_pipe *
*===========================================================================*/
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static int is_pipe(struct filp *f)
{
/* Recognize either anonymous pipe or named pipe (FIFO) */
return(f && f->filp_vno && S_ISFIFO(f->filp_vno->v_mode));
}
/*===========================================================================*
* is_supported_major *
*===========================================================================*/
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static int is_supported_major(struct filp *f)
{
/* See if this filp is a handle on a device on which we support select() */
unsigned int m;
if (!(f && f->filp_vno)) return(FALSE);
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if (!S_ISCHR(f->filp_vno->v_mode)) return(FALSE);
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for (m = 0; m < SEL_MAJORS; m++)
if (major(f->filp_vno->v_sdev) == select_majors[m])
return(TRUE);
return(FALSE);
}
2008-02-22 16:46:59 +01:00
/*===========================================================================*
* select_request_async *
2008-02-22 16:46:59 +01:00
*===========================================================================*/
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static int select_request_async(struct filp *f, int *ops, int block)
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{
int r, rops, major;
struct dmap *dp;
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rops = *ops;
/* By default, nothing to do */
*ops = 0;
if (!block && (f->filp_select_flags & FSF_BLOCKED)) {
/* This filp is blocked waiting for a reply, but we don't want to
* block ourselves. Unless we're awaiting the initial reply, these
* operations won't be ready */
if (!(f->filp_select_flags & FSF_BUSY)) {
if ((rops & SEL_RD) && (f->filp_select_flags & FSF_RD_BLOCK))
rops &= ~SEL_RD;
if ((rops & SEL_WR) && (f->filp_select_flags & FSF_WR_BLOCK))
rops &= ~SEL_WR;
if ((rops & SEL_ERR) && (f->filp_select_flags & FSF_ERR_BLOCK))
rops &= ~SEL_ERR;
if (!(rops & (SEL_RD|SEL_WR|SEL_ERR)))
return(OK);
}
}
f->filp_select_flags |= FSF_UPDATE;
if (block) {
rops |= SEL_NOTIFY;
if (rops & SEL_RD) f->filp_select_flags |= FSF_RD_BLOCK;
if (rops & SEL_WR) f->filp_select_flags |= FSF_WR_BLOCK;
if (rops & SEL_ERR) f->filp_select_flags |= FSF_ERR_BLOCK;
}
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if (f->filp_select_flags & FSF_BUSY)
return(SUSPEND);
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major = major(f->filp_vno->v_sdev);
if (major < 0 || major >= NR_DEVICES) return(ENXIO);
dp = &dmap[major];
if (dp->dmap_sel_filp)
return(SUSPEND);
2008-02-22 16:46:59 +01:00
f->filp_select_flags &= ~FSF_UPDATE;
r = dev_io(VFS_DEV_SELECT, f->filp_vno->v_sdev, rops, NULL,
cvu64(0), 0, 0, FALSE);
if (r < 0 && r != SUSPEND)
return(r);
2012-02-13 16:28:04 +01:00
if (r != SUSPEND)
panic("select_request_asynch: expected SUSPEND got: %d", r);
dp->dmap_sel_filp = f;
f->filp_select_flags |= FSF_BUSY;
return(SUSPEND);
2008-02-22 16:46:59 +01:00
}
/*===========================================================================*
* select_request_file *
*===========================================================================*/
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static int select_request_file(struct filp *UNUSED(f), int *UNUSED(ops),
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int UNUSED(block))
{
/* Files are always ready, so output *ops is input *ops */
return(OK);
}
/*===========================================================================*
* select_request_major *
*===========================================================================*/
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static int select_request_major(struct filp *f, int *ops, int block)
{
int major, r;
major = major(f->filp_vno->v_sdev);
if (major < 0 || major >= NR_DEVICES) return(ENXIO);
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if (dmap[major].dmap_style == STYLE_DEVA ||
dmap[major].dmap_style == STYLE_CLONE_A)
r = select_request_async(f, ops, block);
else
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r = select_request_sync(f, ops, block);
return(r);
}
/*===========================================================================*
* select_request_sync *
*===========================================================================*/
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static int select_request_sync(struct filp *f, int *ops, int block)
{
int rops;
rops = *ops;
if (block) rops |= SEL_NOTIFY;
*ops = dev_io(VFS_DEV_SELECT, f->filp_vno->v_sdev, rops, NULL,
cvu64(0), 0, 0, FALSE);
if (*ops < 0)
return(*ops);
return(OK);
}
/*===========================================================================*
* select_request_pipe *
*===========================================================================*/
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static int select_request_pipe(struct filp *f, int *ops, int block)
{
int orig_ops, r = 0, err;
orig_ops = *ops;
if ((*ops & (SEL_RD|SEL_ERR))) {
/* Check if we can read 1 byte */
err = pipe_check(f, READING, f->filp_flags & ~O_NONBLOCK, 1,
1 /* Check only */);
if (err != SUSPEND)
r |= SEL_RD;
if (err < 0 && err != SUSPEND)
r |= SEL_ERR;
if (err == SUSPEND && !(f->filp_mode & R_BIT)) {
/* A "meaningless" read select, therefore ready
* for reading and no error set. */
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r |= SEL_RD;
r &= ~SEL_ERR;
}
}
if ((*ops & (SEL_WR|SEL_ERR))) {
/* Check if we can write 1 byte */
err = pipe_check(f, WRITING, f->filp_flags & ~O_NONBLOCK, 1,
1 /* Check only */);
if (err != SUSPEND)
r |= SEL_WR;
if (err < 0 && err != SUSPEND)
r |= SEL_ERR;
if (err == SUSPEND && !(f->filp_mode & W_BIT)) {
/* A "meaningless" write select, therefore ready
for writing and no error set. */
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r |= SEL_WR;
r &= ~SEL_ERR;
}
}
/* Some options we collected might not be requested. */
*ops = r & orig_ops;
if (!*ops && block)
f->filp_pipe_select_ops |= orig_ops;
return(OK);
}
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/*===========================================================================*
* tab2ops *
*===========================================================================*/
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static int tab2ops(int fd, struct selectentry *e)
{
int ops = 0;
if (FD_ISSET(fd, &e->readfds)) ops |= SEL_RD;
if (FD_ISSET(fd, &e->writefds)) ops |= SEL_WR;
if (FD_ISSET(fd, &e->errorfds)) ops |= SEL_ERR;
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return(ops);
}
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/*===========================================================================*
* ops2tab *
*===========================================================================*/
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static void ops2tab(int ops, int fd, struct selectentry *e)
{
if ((ops & SEL_RD) && e->vir_readfds && FD_ISSET(fd, &e->readfds) &&
!FD_ISSET(fd, &e->ready_readfds)) {
FD_SET(fd, &e->ready_readfds);
e->nreadyfds++;
}
if ((ops & SEL_WR) && e->vir_writefds && FD_ISSET(fd, &e->writefds) &&
!FD_ISSET(fd, &e->ready_writefds)) {
FD_SET(fd, &e->ready_writefds);
e->nreadyfds++;
}
if ((ops & SEL_ERR) && e->vir_errorfds && FD_ISSET(fd, &e->errorfds) &&
!FD_ISSET(fd, &e->ready_errorfds)) {
FD_SET(fd, &e->ready_errorfds);
e->nreadyfds++;
}
}
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/*===========================================================================*
* copy_fdsets *
*===========================================================================*/
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static int copy_fdsets(struct selectentry *se, int nfds, int direction)
{
int r;
size_t fd_setsize;
endpoint_t src_e, dst_e;
fd_set *src_fds, *dst_fds;
if (nfds < 0 || nfds > OPEN_MAX)
panic("select copy_fdsets: nfds wrong: %d", nfds);
/* Only copy back as many bits as the user expects. */
Build NetBSD libc library in world in ELF mode. 3 sets of libraries are built now: . ack: all libraries that ack can compile (/usr/lib/i386/) . clang+elf: all libraries with minix headers (/usr/lib/) . clang+elf: all libraries with netbsd headers (/usr/netbsd/) Once everything can be compiled with netbsd libraries and headers, the /usr/netbsd hierarchy will be obsolete and its libraries compiled with netbsd headers will be installed in /usr/lib, and its headers in /usr/include. (i.e. minix libc and current minix headers set will be gone.) To use the NetBSD libc system (libraries + headers) before it is the default libc, see: http://wiki.minix3.org/en/DevelopersGuide/UsingNetBSDCode This wiki page also documents the maintenance of the patch files of minix-specific changes to imported NetBSD code. Changes in this commit: . libsys: Add NBSD compilation and create a safe NBSD-based libc. . Port rest of libraries (except libddekit) to new header system. . Enable compilation of libddekit with new headers. . Enable kernel compilation with new headers. . Enable drivers compilation with new headers. . Port legacy commands to new headers and libc. . Port servers to new headers. . Add <sys/sigcontext.h> in compat library. . Remove dependency file in tree. . Enable compilation of common/lib/libc/atomic in libsys . Do not generate RCSID strings in libc. . Temporarily disable zoneinfo as they are incompatible with NetBSD format . obj-nbsd for .gitignore . Procfs: use only integer arithmetic. (Antoine Leca) . Increase ramdisk size to create NBSD-based images. . Remove INCSYMLINKS handling hack. . Add nbsd_include/sys/exec_elf.h . Enable ELF compilation with NBSD libc. . Add 'make nbsdsrc' in tools to download reference NetBSD sources. . Automate minix-port.patch creation. . Avoid using fstavfs() as it is *extremely* slow and unneeded. . Set err() as PRIVATE to avoid name clash with libc. . [NBSD] servers/vm: remove compilation warnings. . u32 is not a long in NBSD headers. . UPDATING info on netbsd hierarchy . commands fixes for netbsd libc
2011-04-27 15:00:52 +02:00
fd_setsize = (size_t) (howmany(nfds, __NFDBITS) * sizeof(__fd_mask));
/* Set source and destination endpoints */
src_e = (direction == FROM_PROC) ? se->req_endpt : SELF;
dst_e = (direction == FROM_PROC) ? SELF : se->req_endpt;
/* read set */
src_fds = (direction == FROM_PROC) ? se->vir_readfds : &se->ready_readfds;
dst_fds = (direction == FROM_PROC) ? &se->readfds : se->vir_readfds;
if (se->vir_readfds) {
r = sys_vircopy(src_e, (vir_bytes) src_fds, dst_e,
(vir_bytes) dst_fds, fd_setsize);
if (r != OK) return(r);
}
/* write set */
src_fds = (direction == FROM_PROC) ? se->vir_writefds : &se->ready_writefds;
dst_fds = (direction == FROM_PROC) ? &se->writefds : se->vir_writefds;
if (se->vir_writefds) {
r = sys_vircopy(src_e, (vir_bytes) src_fds, dst_e,
(vir_bytes) dst_fds, fd_setsize);
if (r != OK) return(r);
}
/* error set */
src_fds = (direction == FROM_PROC) ? se->vir_errorfds : &se->ready_errorfds;
dst_fds = (direction == FROM_PROC) ? &se->errorfds : se->vir_errorfds;
if (se->vir_errorfds) {
r = sys_vircopy(src_e, (vir_bytes) src_fds, dst_e,
(vir_bytes) dst_fds, fd_setsize);
if (r != OK) return(r);
}
return(OK);
}
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/*===========================================================================*
* select_cancel_all *
*===========================================================================*/
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static void select_cancel_all(struct selectentry *se)
{
/* Cancel select. Decrease select usage and cancel timer */
int fd;
struct filp *f;
for (fd = 0; fd < se->nfds; fd++) {
if ((f = se->filps[fd]) == NULL) continue;
se->filps[fd] = NULL;
select_cancel_filp(f);
}
if (se->expiry > 0) {
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cancel_timer(&se->timer);
se->expiry = 0;
}
se->requestor = NULL;
}
/*===========================================================================*
* select_cancel_filp *
*===========================================================================*/
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static void select_cancel_filp(struct filp *f)
{
/* Reduce number of select users of this filp */
assert(f);
assert(f->filp_selectors >= 0);
if (f->filp_selectors == 0) return;
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if (f->filp_count == 0) return;
select_lock_filp(f, f->filp_select_ops);
f->filp_selectors--;
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if (f->filp_selectors == 0) {
/* No one selecting on this filp anymore, forget about select state */
f->filp_select_ops = 0;
f->filp_select_flags = 0;
f->filp_pipe_select_ops = 0;
}
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unlock_filp(f);
}
/*===========================================================================*
* select_return *
*===========================================================================*/
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static void select_return(struct selectentry *se)
{
int r, r1;
assert(!is_deferred(se)); /* Not done yet, first wait for async reply */
select_cancel_all(se);
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r1 = copy_fdsets(se, se->nfds, TO_PROC);
if (r1 != OK)
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r = r1;
else if (se->error != OK)
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r = se->error;
else
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r = se->nreadyfds;
revive(se->req_endpt, r);
}
/*===========================================================================*
* select_callback *
*===========================================================================*/
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void select_callback(struct filp *f, int status)
{
filp_status(f, status);
}
/*===========================================================================*
* init_select *
*===========================================================================*/
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void init_select(void)
{
int s;
for (s = 0; s < MAXSELECTS; s++)
init_timer(&selecttab[s].timer);
}
/*===========================================================================*
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* select_forget *
*===========================================================================*/
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void select_forget(endpoint_t proc_e)
{
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/* Something has happened (e.g. signal delivered that interrupts select()).
* Totally forget about the select(). */
int slot;
struct selectentry *se;
for (slot = 0; slot < MAXSELECTS; slot++) {
se = &selecttab[slot];
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if (se->requestor != NULL && se->req_endpt == proc_e)
break;
}
if (slot >= MAXSELECTS) return; /* Entry not found */
se->error = EINTR;
if (is_deferred(se)) return; /* Still awaiting initial reply */
select_cancel_all(se);
}
/*===========================================================================*
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* select_timeout_check *
*===========================================================================*/
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void select_timeout_check(timer_t *timer)
{
int s;
struct selectentry *se;
s = tmr_arg(timer)->ta_int;
if (s < 0 || s >= MAXSELECTS) return; /* Entry does not exist */
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se = &selecttab[s];
if (se->requestor == NULL) return;
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fp = se->requestor;
if (se->expiry <= 0) return; /* Strange, did we even ask for a timeout? */
se->expiry = 0;
if (is_deferred(se)) return; /* Wait for initial replies to DEV_SELECT */
select_return(se);
}
/*===========================================================================*
endpoint-aware conversion of servers. 'who', indicating caller number in pm and fs and some other servers, has been removed in favour of 'who_e' (endpoint) and 'who_p' (proc nr.). In both PM and FS, isokendpt() convert endpoints to process slot numbers, returning OK if it was a valid and consistent endpoint number. okendpt() does the same but panic()s if it doesn't succeed. (In PM, this is pm_isok..) pm and fs keep their own records of process endpoints in their proc tables, which are needed to make kernel calls about those processes. message field names have changed. fs drivers are endpoints. fs now doesn't try to get out of driver deadlock, as the protocol isn't supposed to let that happen any more. (A warning is printed if ELOCKED is detected though.) fproc[].fp_task (indicating which driver the process is suspended on) became an int. PM and FS now get endpoint numbers of initial boot processes from the kernel. These happen to be the same as the old proc numbers, to let user processes reach them with the old numbers, but FS and PM don't know that. All new processes after INIT, even after the generation number wraps around, get endpoint numbers with generation 1 and higher, so the first instances of the boot processes are the only processes ever to have endpoint numbers in the old proc number range. More return code checks of sys_* functions have been added. IS has become endpoint-aware. Ditched the 'text' and 'data' fields in the kernel dump (which show locations, not sizes, so aren't terribly useful) in favour of the endpoint number. Proc number is still visible. Some other dumps (e.g. dmap, rs) show endpoint numbers now too which got the formatting changed. PM reading segments using rw_seg() has changed - it uses other fields in the message now instead of encoding the segment and process number and fd in the fd field. For that it uses _read_pm() and _write_pm() which to _taskcall()s directly in pm/misc.c. PM now sys_exit()s itself on panic(), instead of sys_abort(). RS also talks in endpoints instead of process numbers.
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* select_unsuspend_by_endpt *
*===========================================================================*/
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void select_unsuspend_by_endpt(endpoint_t proc_e)
{
/* Revive blocked processes when a driver has disappeared */
int fd, s, major;
struct selectentry *se;
struct filp *f;
for (s = 0; s < MAXSELECTS; s++) {
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int wakehim = 0;
se = &selecttab[s];
if (se->requestor == NULL) continue;
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if (se->requestor->fp_endpoint == proc_e) {
assert(se->requestor->fp_flags & FP_EXITING);
select_cancel_all(se);
continue;
}
for (fd = 0; fd < se->nfds; fd++) {
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if ((f = se->filps[fd]) == NULL || f->filp_vno == NULL)
continue;
major = major(f->filp_vno->v_sdev);
if (dmap_driver_match(proc_e, major)) {
se->filps[fd] = NULL;
se->error = EINTR;
select_cancel_filp(f);
wakehim = 1;
}
}
if (wakehim && !is_deferred(se))
select_return(se);
}
}
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/*===========================================================================*
* select_reply1 *
*===========================================================================*/
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void select_reply1(driver_e, minor, status)
endpoint_t driver_e;
int minor;
int status;
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{
/* Handle reply to DEV_SELECT request */
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int major;
dev_t dev;
struct filp *f;
struct dmap *dp;
struct vnode *vp;
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/* Figure out which device is replying */
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if ((dp = get_dmap(driver_e)) == NULL) return;
major = dp-dmap;
dev = makedev(major, minor);
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/* Get filp belonging to character special file */
if ((f = dp->dmap_sel_filp) == NULL) {
printf("VFS (%s:%d): major %d was not expecting a DEV_SELECT reply\n",
__FILE__, __LINE__, major);
return;
}
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/* Is the filp still in use and busy waiting for a reply? The owner might
* have vanished before the driver was able to reply. */
if (f->filp_count >= 1 && (f->filp_select_flags & FSF_BUSY)) {
/* Find vnode and check we got a reply from the device we expected */
vp = f->filp_vno;
assert(vp != NULL);
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assert(S_ISCHR(vp->v_mode));
if (vp->v_sdev != dev) {
printf("VFS (%s:%d): expected reply from dev %d not %d\n",
__FILE__, __LINE__, vp->v_sdev, dev);
return;
}
}
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/* No longer waiting for a reply from this device */
dp->dmap_sel_filp = NULL;
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/* Process select result only if requestor is still around. That is, the
* corresponding filp is still in use.
*/
if (f->filp_count >= 1) {
select_lock_filp(f, f->filp_select_ops);
f->filp_select_flags &= ~FSF_BUSY;
/* The select call is done now, except when
* - another process started a select on the same filp with possibly a
* different set of operations.
* - a process does a select on the same filp but using different file
* descriptors.
* - the select has a timeout. Upon receiving this reply the operations
* might not be ready yet, so we want to wait for that to ultimately
* happen.
* Therefore we need to keep remembering what the operations are.
*/
if (!(f->filp_select_flags & (FSF_UPDATE|FSF_BLOCKED)))
f->filp_select_ops = 0; /* done selecting */
else if (!(f->filp_select_flags & FSF_UPDATE))
/* there may be operations pending */
f->filp_select_ops &= ~status;
/* Record new filp status */
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if (!(status == 0 && (f->filp_select_flags & FSF_BLOCKED))) {
if (status > 0) { /* operations ready */
if (status & SEL_RD)
f->filp_select_flags &= ~FSF_RD_BLOCK;
if (status & SEL_WR)
f->filp_select_flags &= ~FSF_WR_BLOCK;
if (status & SEL_ERR)
f->filp_select_flags &= ~FSF_ERR_BLOCK;
} else if (status < 0) { /* error */
/* Always unblock upon error */
f->filp_select_flags &= ~FSF_BLOCKED;
}
}
unlock_filp(f);
filp_status(f, status); /* Tell filp owners about the results */
}
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select_restart_filps();
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}
/*===========================================================================*
* select_reply2 *
*===========================================================================*/
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void select_reply2(driver_e, minor, status)
endpoint_t driver_e;
int minor;
int status;
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{
/* Handle secondary reply to DEV_SELECT request. A secondary reply occurs when
* the select request is 'blocking' until an operation becomes ready. */
int major, slot, fd;
dev_t dev;
struct filp *f;
struct dmap *dp;
struct vnode *vp;
struct selectentry *se;
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if (status == 0) {
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printf("VFS (%s:%d): weird status (%d) to report\n",
__FILE__, __LINE__, status);
return;
}
/* Figure out which device is replying */
if ((dp = get_dmap(driver_e)) == NULL) {
printf("VFS (%s:%d): endpoint %d is not a known driver endpoint\n",
__FILE__, __LINE__, driver_e);
return;
}
major = dp-dmap;
dev = makedev(major, minor);
/* Find all file descriptors selecting for this device */
for (slot = 0; slot < MAXSELECTS; slot++) {
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se = &selecttab[slot];
if (se->requestor == NULL) continue; /* empty slot */
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for (fd = 0; fd < se->nfds; fd++) {
if ((f = se->filps[fd]) == NULL) continue;
if ((vp = f->filp_vno) == NULL) continue;
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if (!S_ISCHR(vp->v_mode)) continue;
if (vp->v_sdev != dev) continue;
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select_lock_filp(f, f->filp_select_ops);
if (status > 0) { /* Operations ready */
/* Clear the replied bits from the request
* mask unless FSF_UPDATE is set.
*/
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if (!(f->filp_select_flags & FSF_UPDATE))
f->filp_select_ops &= ~status;
if (status & SEL_RD)
f->filp_select_flags &= ~FSF_RD_BLOCK;
if (status & SEL_WR)
f->filp_select_flags &= ~FSF_WR_BLOCK;
if (status & SEL_ERR)
f->filp_select_flags &= ~FSF_ERR_BLOCK;
ops2tab(status, fd, se);
} else {
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f->filp_select_flags &= ~FSF_BLOCKED;
ops2tab(SEL_RD|SEL_WR|SEL_ERR, fd, se);
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}
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unlock_filp(f);
if (se->nreadyfds > 0) restart_proc(se);
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}
}
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select_restart_filps();
}
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/*===========================================================================*
* select_restart_filps *
*===========================================================================*/
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static void select_restart_filps()
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{
int fd, slot;
struct filp *f;
struct vnode *vp;
struct selectentry *se;
/* Locate filps that can be restarted */
for (slot = 0; slot < MAXSELECTS; slot++) {
se = &selecttab[slot];
if (se->requestor == NULL) continue; /* empty slot */
/* Only 'deferred' processes are eligible to restart */
if (!is_deferred(se)) continue;
/* Find filps that are not waiting for a reply, but have an updated
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* status (i.e., another select on the same filp with possibly a
* different set of operations is to be done), and thus requires the
* select request to be sent again).
*/
for (fd = 0; fd < se->nfds; fd++) {
int r, wantops, ops;
if ((f = se->filps[fd]) == NULL) continue;
if (f->filp_select_flags & FSF_BUSY) /* Still waiting for */
continue; /* initial reply */
if (!(f->filp_select_flags & FSF_UPDATE)) /* Must be in */
continue; /* 'update' state */
wantops = ops = f->filp_select_ops;
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vp = f->filp_vno;
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assert(S_ISCHR(vp->v_mode));
r = do_select_request(se, fd, &wantops);
if (r != OK && r != SUSPEND)
break; /* Error or bogus return code; abort */
if (wantops & ops) ops2tab(wantops, fd, se);
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}
}
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}
/*===========================================================================*
* do_select_request *
*===========================================================================*/
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static int do_select_request(se, fd, ops)
struct selectentry *se;
int fd;
int *ops;
{
/* Perform actual select request for file descriptor fd */
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int r, type;
struct filp *f;
type = se->type[fd];
f = se->filps[fd];
select_lock_filp(f, *ops);
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r = fdtypes[type].select_request(f, ops, se->block);
unlock_filp(f);
if (r != OK && r != SUSPEND) {
se->error = EINTR;
se->block = 0; /* Stop blocking to return asap */
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if (!is_deferred(se)) select_cancel_all(se);
}
return(r);
}
/*===========================================================================*
* filp_status *
*===========================================================================*/
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static void filp_status(f, status)
struct filp *f;
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int status;
{
/* Tell processes that need to know about the status of this filp */
int fd, slot;
struct selectentry *se;
for (slot = 0; slot < MAXSELECTS; slot++) {
se = &selecttab[slot];
if (se->requestor == NULL) continue; /* empty slot */
for (fd = 0; fd < se->nfds; fd++) {
if (se->filps[fd] != f) continue;
if (status < 0)
ops2tab(SEL_RD|SEL_WR|SEL_ERR, fd, se);
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else
ops2tab(status, fd, se);
restart_proc(se);
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}
}
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}
/*===========================================================================*
* restart_proc *
*===========================================================================*/
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static void restart_proc(se)
struct selectentry *se;
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{
/* Tell process about select results (if any) unless there are still results
* pending. */
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if ((se->nreadyfds > 0 || !se->block) && !is_deferred(se))
select_return(se);
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}
/*===========================================================================*
* wipe_select *
*===========================================================================*/
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static void wipe_select(struct selectentry *se)
{
se->nfds = 0;
se->nreadyfds = 0;
se->error = OK;
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se->block = 0;
memset(se->filps, 0, sizeof(se->filps));
FD_ZERO(&se->readfds);
FD_ZERO(&se->writefds);
FD_ZERO(&se->errorfds);
FD_ZERO(&se->ready_readfds);
FD_ZERO(&se->ready_writefds);
FD_ZERO(&se->ready_errorfds);
}
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/*===========================================================================*
* select_lock_filp *
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*===========================================================================*/
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static void select_lock_filp(struct filp *f, int ops)
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{
/* Lock a filp and vnode based on which operations are requested */
tll_access_t locktype;;
locktype = VNODE_READ; /* By default */
if (ops & (SEL_WR|SEL_ERR))
/* Selecting for error or writing requires exclusive access */
locktype = VNODE_WRITE;
lock_filp(f, locktype);
}