haiku/src/system/kernel/fs/fd.cpp

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/* Operations on file descriptors
*
* Copyright 2002-2007, Axel Dörfler, axeld@pinc-software.de.
* Distributed under the terms of the MIT License.
*/
#include <fd.h>
#include <stdlib.h>
#include <string.h>
#include <OS.h>
#include <syscalls.h>
#include <util/AutoLock.h>
#include <vfs.h>
#include "vfs_select.h"
//#define TRACE_FD
#ifdef TRACE_FD
# define TRACE(x) dprintf x
#else
# define TRACE(x)
#endif
static void deselect_select_infos(file_descriptor* descriptor,
select_info* infos);
/*** General fd routines ***/
#ifdef DEBUG
void dump_fd(int fd, struct file_descriptor *descriptor);
void
dump_fd(int fd,struct file_descriptor *descriptor)
{
dprintf("fd[%d] = %p: type = %ld, ref_count = %ld, ops = %p, u.vnode = %p, u.mount = %p, cookie = %p, open_mode = %lx, pos = %Ld\n",
fd, descriptor, descriptor->type, descriptor->ref_count, descriptor->ops,
descriptor->u.vnode, descriptor->u.mount, descriptor->cookie, descriptor->open_mode, descriptor->pos);
}
#endif
/** Allocates and initializes a new file_descriptor */
struct file_descriptor *
alloc_fd(void)
{
file_descriptor *descriptor
= (file_descriptor*)malloc(sizeof(struct file_descriptor));
if (descriptor == NULL)
return NULL;
descriptor->u.vnode = NULL;
descriptor->cookie = NULL;
descriptor->ref_count = 1;
descriptor->open_count = 0;
descriptor->open_mode = 0;
descriptor->pos = 0;
return descriptor;
}
bool
fd_close_on_exec(struct io_context *context, int fd)
{
return CHECK_BIT(context->fds_close_on_exec[fd / 8], fd & 7) ? true : false;
}
void
fd_set_close_on_exec(struct io_context *context, int fd, bool closeFD)
{
if (closeFD)
context->fds_close_on_exec[fd / 8] |= (1 << (fd & 7));
else
context->fds_close_on_exec[fd / 8] &= ~(1 << (fd & 7));
}
/** Searches a free slot in the FD table of the provided I/O context, and inserts
* the specified descriptor into it.
*/
int
new_fd_etc(struct io_context *context, struct file_descriptor *descriptor, int firstIndex)
{
int fd = -1;
uint32 i;
mutex_lock(&context->io_mutex);
for (i = firstIndex; i < context->table_size; i++) {
if (!context->fds[i]) {
fd = i;
break;
}
}
if (fd < 0) {
fd = B_NO_MORE_FDS;
goto err;
}
context->fds[fd] = descriptor;
context->num_used_fds++;
atomic_add(&descriptor->open_count, 1);
err:
mutex_unlock(&context->io_mutex);
return fd;
}
int
new_fd(struct io_context *context, struct file_descriptor *descriptor)
{
return new_fd_etc(context, descriptor, 0);
}
/** Reduces the descriptor's reference counter, and frees all resources
* when it's no longer used.
*/
void
put_fd(struct file_descriptor *descriptor)
{
int32 previous = atomic_add(&descriptor->ref_count, -1);
TRACE(("put_fd(descriptor = %p [ref = %ld, cookie = %p])\n",
descriptor, descriptor->ref_count, descriptor->cookie));
// free the descriptor if we don't need it anymore
if (previous == 1) {
// free the underlying object
if (descriptor->ops != NULL && descriptor->ops->fd_free != NULL)
descriptor->ops->fd_free(descriptor);
free(descriptor);
} else if ((descriptor->open_mode & O_DISCONNECTED) != 0
&& previous - 1 == descriptor->open_count
&& descriptor->ops != NULL) {
// the descriptor has been disconnected - it cannot
// be accessed anymore, let's close it (no one is
// currently accessing this descriptor)
if (descriptor->ops->fd_close)
descriptor->ops->fd_close(descriptor);
if (descriptor->ops->fd_free)
descriptor->ops->fd_free(descriptor);
// prevent this descriptor from being closed/freed again
descriptor->open_count = -1;
descriptor->ref_count = -1;
descriptor->ops = NULL;
descriptor->u.vnode = NULL;
// the file descriptor is kept intact, so that it's not
// reused until someone explicetly closes it
}
}
/** Decrements the open counter of the file descriptor and invokes
* its close hook when appropriate.
*/
void
close_fd(struct file_descriptor *descriptor)
{
if (atomic_add(&descriptor->open_count, -1) == 1) {
vfs_unlock_vnode_if_locked(descriptor);
if (descriptor->ops != NULL && descriptor->ops->fd_close != NULL)
descriptor->ops->fd_close(descriptor);
}
}
/** This descriptor's underlying object will be closed and freed
* as soon as possible (in one of the next calls to put_fd() -
* get_fd() will no longer succeed on this descriptor).
* This is useful if the underlying object is gone, for instance
* when a (mounted) volume got removed unexpectedly.
*/
void
disconnect_fd(struct file_descriptor *descriptor)
{
descriptor->open_mode |= O_DISCONNECTED;
}
void
inc_fd_ref_count(struct file_descriptor *descriptor)
{
atomic_add(&descriptor->ref_count, 1);
}
static struct file_descriptor *
get_fd_locked(struct io_context *context, int fd)
{
if (fd < 0 || (uint32)fd >= context->table_size)
return NULL;
struct file_descriptor *descriptor = context->fds[fd];
if (descriptor != NULL) {
// Disconnected descriptors cannot be accessed anymore
if (descriptor->open_mode & O_DISCONNECTED)
descriptor = NULL;
else
inc_fd_ref_count(descriptor);
}
return descriptor;
}
struct file_descriptor *
get_fd(struct io_context *context, int fd)
{
MutexLocker(context->io_mutex);
return get_fd_locked(context, fd);
}
/** Removes the file descriptor from the specified slot.
*/
static struct file_descriptor *
remove_fd(struct io_context *context, int fd)
{
struct file_descriptor *descriptor = NULL;
if (fd < 0)
return NULL;
mutex_lock(&context->io_mutex);
if ((uint32)fd < context->table_size)
descriptor = context->fds[fd];
select_info* selectInfos = NULL;
bool disconnected = false;
if (descriptor) {
// fd is valid
context->fds[fd] = NULL;
fd_set_close_on_exec(context, fd, false);
context->num_used_fds--;
selectInfos = context->select_infos[fd];
context->select_infos[fd] = NULL;
disconnected = (descriptor->open_mode & O_DISCONNECTED);
}
mutex_unlock(&context->io_mutex);
if (selectInfos != NULL)
deselect_select_infos(descriptor, selectInfos);
return disconnected ? NULL : descriptor;
}
static int
dup_fd(int fd, bool kernel)
{
struct io_context *context = get_current_io_context(kernel);
struct file_descriptor *descriptor;
int status;
TRACE(("dup_fd: fd = %d\n", fd));
// Try to get the fd structure
descriptor = get_fd(context, fd);
if (descriptor == NULL)
return B_FILE_ERROR;
// now put the fd in place
status = new_fd(context, descriptor);
if (status < 0)
put_fd(descriptor);
else {
mutex_lock(&context->io_mutex);
fd_set_close_on_exec(context, status, false);
mutex_unlock(&context->io_mutex);
}
return status;
}
/** POSIX says this should be the same as:
* close(newfd);
* fcntl(oldfd, F_DUPFD, newfd);
*
* We do dup2() directly to be thread-safe.
*/
static int
dup2_fd(int oldfd, int newfd, bool kernel)
{
struct file_descriptor *evicted = NULL;
struct io_context *context;
TRACE(("dup2_fd: ofd = %d, nfd = %d\n", oldfd, newfd));
// quick check
if (oldfd < 0 || newfd < 0)
return B_FILE_ERROR;
// Get current I/O context and lock it
context = get_current_io_context(kernel);
mutex_lock(&context->io_mutex);
// Check if the fds are valid (mutex must be locked because
// the table size could be changed)
if ((uint32)oldfd >= context->table_size
|| (uint32)newfd >= context->table_size
|| context->fds[oldfd] == NULL) {
mutex_unlock(&context->io_mutex);
return B_FILE_ERROR;
}
// Check for identity, note that it cannot be made above
// because we always want to return an error on invalid
// handles
select_info* selectInfos = NULL;
if (oldfd != newfd) {
// Now do the work
evicted = context->fds[newfd];
selectInfos = context->select_infos[newfd];
context->select_infos[newfd] = NULL;
atomic_add(&context->fds[oldfd]->ref_count, 1);
atomic_add(&context->fds[oldfd]->open_count, 1);
context->fds[newfd] = context->fds[oldfd];
if (evicted == NULL)
context->num_used_fds++;
}
fd_set_close_on_exec(context, newfd, false);
mutex_unlock(&context->io_mutex);
// Say bye bye to the evicted fd
if (evicted) {
deselect_select_infos(evicted, selectInfos);
close_fd(evicted);
put_fd(evicted);
}
return newfd;
}
static status_t
fd_ioctl(bool kernelFD, int fd, ulong op, void *buffer, size_t length)
{
struct file_descriptor *descriptor;
int status;
descriptor = get_fd(get_current_io_context(kernelFD), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (descriptor->ops->fd_ioctl)
status = descriptor->ops->fd_ioctl(descriptor, op, buffer, length);
else
status = EOPNOTSUPP;
put_fd(descriptor);
return status;
}
static void
deselect_select_infos(file_descriptor* descriptor, select_info* infos)
{
TRACE(("deselect_select_infos(%p, %p)\n", descriptor, infos));
select_info* info = infos;
while (info != NULL) {
select_sync* sync = info->sync;
// deselect the selected events
if (descriptor->ops->fd_deselect && info->selected_events) {
for (uint16 event = 1; event < 16; event++) {
if (info->selected_events & SELECT_FLAG(event)) {
descriptor->ops->fd_deselect(descriptor, event,
(selectsync*)info);
}
}
}
info = info->next;
put_select_sync(sync);
}
}
status_t
select_fd(int fd, struct select_sync* sync, uint32 ref, bool kernel)
{
TRACE(("select_fd(fd = %d, selectsync = %p, ref = %lu, 0x%x)\n", fd, sync, ref, sync->set[ref].selected_events));
select_info* info = &sync->set[ref];
if (info->selected_events == 0)
return B_OK;
io_context* context = get_current_io_context(kernel);
MutexLocker locker(context->io_mutex);
struct file_descriptor* descriptor = get_fd_locked(context, fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (!descriptor->ops->fd_select) {
// if the I/O subsystem doesn't support select(), we will
// immediately notify the select call
locker.Unlock();
put_fd(descriptor);
return notify_select_events(info, info->selected_events);
}
// add the info to the IO context
info->next = context->select_infos[fd];
context->select_infos[fd] = info;
// as long as the info is in the list, we keep a reference to the sync
// object
atomic_add(&sync->ref_count, 1);
locker.Unlock();
// select any events asked for
uint32 selectedEvents = 0;
for (uint16 event = 1; event < 16; event++) {
if (info->selected_events & SELECT_FLAG(event)
&& descriptor->ops->fd_select(descriptor, event, ref,
(selectsync*)info) == B_OK) {
selectedEvents |= SELECT_FLAG(event);
}
}
info->selected_events = selectedEvents;
// if nothing has been selected, we deselect immediately
if (selectedEvents == 0)
deselect_fd(fd, sync, ref, kernel);
put_fd(descriptor);
return B_OK;
}
status_t
deselect_fd(int fd, struct select_sync* sync, uint32 ref, bool kernel)
{
TRACE(("deselect_fd(fd = %d, selectsync = %p, ref = %lu)\n", fd, sync, ref));
select_info* info = &sync->set[ref];
if (info->selected_events == 0)
return B_OK;
io_context* context = get_current_io_context(kernel);
MutexLocker locker(context->io_mutex);
struct file_descriptor* descriptor = get_fd_locked(context, fd);
if (descriptor == NULL)
return B_FILE_ERROR;
// remove the info from the IO context
select_info** infoLocation = &context->select_infos[fd];
while (*infoLocation != NULL && *infoLocation != info)
infoLocation = &(*infoLocation)->next;
// If not found, someone else beat us to it.
if (*infoLocation != info) {
locker.Unlock();
put_fd(descriptor);
return B_OK;
}
*infoLocation = info->next;
locker.Unlock();
// deselect the selected events
if (descriptor->ops->fd_deselect && info->selected_events) {
for (uint16 event = 1; event < 16; event++) {
if (info->selected_events & SELECT_FLAG(event)) {
descriptor->ops->fd_deselect(descriptor, event,
(selectsync*)info);
}
}
}
put_select_sync(sync);
put_fd(descriptor);
return B_OK;
}
/** This function checks if the specified fd is valid in the current
* context. It can be used for a quick check; the fd is not locked
* so it could become invalid immediately after this check.
*/
bool
fd_is_valid(int fd, bool kernel)
{
struct file_descriptor *descriptor = get_fd(get_current_io_context(kernel), fd);
if (descriptor == NULL)
return false;
put_fd(descriptor);
return true;
}
struct vnode *
fd_vnode(struct file_descriptor *descriptor)
{
switch (descriptor->type) {
case FDTYPE_FILE:
case FDTYPE_DIR:
case FDTYPE_ATTR_DIR:
case FDTYPE_ATTR:
return descriptor->u.vnode;
}
return NULL;
}
static status_t
common_close(int fd, bool kernel)
{
struct io_context *io = get_current_io_context(kernel);
struct file_descriptor *descriptor = remove_fd(io, fd);
if (descriptor == NULL)
return B_FILE_ERROR;
#ifdef TRACE_FD
if (!kernel)
TRACE(("_user_close(descriptor = %p)\n", descriptor));
#endif
close_fd(descriptor);
put_fd(descriptor);
// the reference associated with the slot
return B_OK;
}
// #pragma mark -
// User syscalls
ssize_t
_user_read(int fd, off_t pos, void *buffer, size_t length)
{
struct file_descriptor *descriptor;
ssize_t bytesRead;
/* This is a user_function, so abort if we have a kernel address */
if (!IS_USER_ADDRESS(buffer))
return B_BAD_ADDRESS;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(false), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_WRONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_read) {
bytesRead = descriptor->ops->fd_read(descriptor, pos, buffer, &length);
if (bytesRead >= B_OK) {
if (length > SSIZE_MAX)
bytesRead = SSIZE_MAX;
else
bytesRead = (ssize_t)length;
descriptor->pos = pos + length;
}
} else
bytesRead = B_BAD_VALUE;
put_fd(descriptor);
return bytesRead;
}
ssize_t
_user_readv(int fd, off_t pos, const iovec *userVecs, size_t count)
{
struct file_descriptor *descriptor;
ssize_t bytesRead = 0;
status_t status;
iovec *vecs;
uint32 i;
/* This is a user_function, so abort if we have a kernel address */
if (!IS_USER_ADDRESS(userVecs))
return B_BAD_ADDRESS;
if (pos < -1)
return B_BAD_VALUE;
/* prevent integer overflow exploit in malloc() */
if (count > IOV_MAX)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(false), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_WRONLY) {
status = B_FILE_ERROR;
goto err1;
}
vecs = (iovec*)malloc(sizeof(iovec) * count);
if (vecs == NULL) {
status = B_NO_MEMORY;
goto err1;
}
if (user_memcpy(vecs, userVecs, sizeof(iovec) * count) < B_OK) {
status = B_BAD_ADDRESS;
goto err2;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_read) {
for (i = 0; i < count; i++) {
size_t length = vecs[i].iov_len;
status = descriptor->ops->fd_read(descriptor, pos, vecs[i].iov_base, &length);
if (status < B_OK) {
bytesRead = status;
break;
}
if ((uint64)bytesRead + length > SSIZE_MAX)
bytesRead = SSIZE_MAX;
else
bytesRead += (ssize_t)length;
pos += vecs[i].iov_len;
}
} else
bytesRead = B_BAD_VALUE;
status = bytesRead;
descriptor->pos = pos;
err2:
free(vecs);
err1:
put_fd(descriptor);
return status;
}
ssize_t
_user_write(int fd, off_t pos, const void *buffer, size_t length)
{
struct file_descriptor *descriptor;
ssize_t bytesWritten = 0;
if (IS_KERNEL_ADDRESS(buffer))
return B_BAD_ADDRESS;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(false), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_RDONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_write) {
bytesWritten = descriptor->ops->fd_write(descriptor, pos, buffer, &length);
if (bytesWritten >= B_OK) {
if (length > SSIZE_MAX)
bytesWritten = SSIZE_MAX;
else
bytesWritten = (ssize_t)length;
descriptor->pos = pos + length;
}
} else
bytesWritten = B_BAD_VALUE;
put_fd(descriptor);
return bytesWritten;
}
ssize_t
_user_writev(int fd, off_t pos, const iovec *userVecs, size_t count)
{
struct file_descriptor *descriptor;
ssize_t bytesWritten = 0;
status_t status;
iovec *vecs;
uint32 i;
/* This is a user_function, so abort if we have a kernel address */
if (!IS_USER_ADDRESS(userVecs))
return B_BAD_ADDRESS;
if (pos < -1)
return B_BAD_VALUE;
/* prevent integer overflow exploit in malloc() */
if (count > IOV_MAX)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(false), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_RDONLY) {
status = B_FILE_ERROR;
goto err1;
}
vecs = (iovec*)malloc(sizeof(iovec) * count);
if (vecs == NULL) {
status = B_NO_MEMORY;
goto err1;
}
if (user_memcpy(vecs, userVecs, sizeof(iovec) * count) < B_OK) {
status = B_BAD_ADDRESS;
goto err2;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_write) {
for (i = 0; i < count; i++) {
size_t length = vecs[i].iov_len;
status = descriptor->ops->fd_write(descriptor, pos, vecs[i].iov_base, &length);
if (status < B_OK) {
bytesWritten = status;
break;
}
if ((uint64)bytesWritten + length > SSIZE_MAX)
bytesWritten = SSIZE_MAX;
else
bytesWritten += (ssize_t)length;
pos += vecs[i].iov_len;
}
} else
bytesWritten = B_BAD_VALUE;
status = bytesWritten;
descriptor->pos = pos;
err2:
free(vecs);
err1:
put_fd(descriptor);
return status;
}
off_t
_user_seek(int fd, off_t pos, int seekType)
{
struct file_descriptor *descriptor;
descriptor = get_fd(get_current_io_context(false), fd);
if (!descriptor)
return B_FILE_ERROR;
TRACE(("user_seek(descriptor = %p)\n", descriptor));
if (descriptor->ops->fd_seek)
pos = descriptor->ops->fd_seek(descriptor, pos, seekType);
else
pos = ESPIPE;
put_fd(descriptor);
return pos;
}
status_t
_user_ioctl(int fd, ulong op, void *buffer, size_t length)
{
struct file_descriptor *descriptor;
int status;
if (IS_KERNEL_ADDRESS(buffer))
return B_BAD_ADDRESS;
TRACE(("user_ioctl: fd %d\n", fd));
return fd_ioctl(false, fd, op, buffer, length);
}
ssize_t
_user_read_dir(int fd, struct dirent *buffer, size_t bufferSize, uint32 maxCount)
{
struct file_descriptor *descriptor;
ssize_t retval;
if (IS_KERNEL_ADDRESS(buffer))
return B_BAD_ADDRESS;
TRACE(("user_read_dir(fd = %d, buffer = %p, bufferSize = %ld, count = %lu)\n", fd, buffer, bufferSize, maxCount));
descriptor = get_fd(get_current_io_context(false), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (descriptor->ops->fd_read_dir) {
uint32 count = maxCount;
retval = descriptor->ops->fd_read_dir(descriptor, buffer, bufferSize, &count);
if (retval >= 0)
retval = count;
} else
retval = EOPNOTSUPP;
put_fd(descriptor);
return retval;
}
status_t
_user_rewind_dir(int fd)
{
struct file_descriptor *descriptor;
status_t status;
TRACE(("user_rewind_dir(fd = %d)\n", fd));
descriptor = get_fd(get_current_io_context(false), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (descriptor->ops->fd_rewind_dir)
status = descriptor->ops->fd_rewind_dir(descriptor);
else
status = EOPNOTSUPP;
put_fd(descriptor);
return status;
}
status_t
_user_close(int fd)
{
return common_close(fd, false);
}
int
_user_dup(int fd)
{
return dup_fd(fd, false);
}
int
_user_dup2(int ofd, int nfd)
{
return dup2_fd(ofd, nfd, false);
}
// #pragma mark -
// Kernel calls
ssize_t
_kern_read(int fd, off_t pos, void *buffer, size_t length)
{
struct file_descriptor *descriptor;
ssize_t bytesRead;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(true), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_WRONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_read) {
bytesRead = descriptor->ops->fd_read(descriptor, pos, buffer, &length);
if (bytesRead >= B_OK) {
if (length > SSIZE_MAX)
bytesRead = SSIZE_MAX;
else
bytesRead = (ssize_t)length;
descriptor->pos = pos + length;
}
} else
bytesRead = B_BAD_VALUE;
put_fd(descriptor);
return bytesRead;
}
ssize_t
_kern_readv(int fd, off_t pos, const iovec *vecs, size_t count)
{
struct file_descriptor *descriptor;
ssize_t bytesRead = 0;
status_t status;
uint32 i;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(true), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_WRONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_read) {
for (i = 0; i < count; i++) {
size_t length = vecs[i].iov_len;
status = descriptor->ops->fd_read(descriptor, pos, vecs[i].iov_base, &length);
if (status < B_OK) {
bytesRead = status;
break;
}
if ((uint64)bytesRead + length > SSIZE_MAX)
bytesRead = SSIZE_MAX;
else
bytesRead += (ssize_t)length;
pos += vecs[i].iov_len;
}
} else
bytesRead = B_BAD_VALUE;
descriptor->pos = pos;
put_fd(descriptor);
return bytesRead;
}
ssize_t
_kern_write(int fd, off_t pos, const void *buffer, size_t length)
{
struct file_descriptor *descriptor;
ssize_t bytesWritten;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(true), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_RDONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_write) {
bytesWritten = descriptor->ops->fd_write(descriptor, pos, buffer, &length);
if (bytesWritten >= B_OK) {
if (length > SSIZE_MAX)
bytesWritten = SSIZE_MAX;
else
bytesWritten = (ssize_t)length;
descriptor->pos = pos + length;
}
} else
bytesWritten = B_BAD_VALUE;
put_fd(descriptor);
return bytesWritten;
}
ssize_t
_kern_writev(int fd, off_t pos, const iovec *vecs, size_t count)
{
struct file_descriptor *descriptor;
ssize_t bytesWritten = 0;
status_t status;
uint32 i;
if (pos < -1)
return B_BAD_VALUE;
descriptor = get_fd(get_current_io_context(true), fd);
if (!descriptor)
return B_FILE_ERROR;
if ((descriptor->open_mode & O_RWMASK) == O_RDONLY) {
put_fd(descriptor);
return B_FILE_ERROR;
}
if (pos == -1)
pos = descriptor->pos;
if (descriptor->ops->fd_write) {
for (i = 0; i < count; i++) {
size_t length = vecs[i].iov_len;
status = descriptor->ops->fd_write(descriptor, pos, vecs[i].iov_base, &length);
if (status < B_OK) {
bytesWritten = status;
break;
}
if ((uint64)bytesWritten + length > SSIZE_MAX)
bytesWritten = SSIZE_MAX;
else
bytesWritten += (ssize_t)length;
pos += vecs[i].iov_len;
}
} else
bytesWritten = B_BAD_VALUE;
descriptor->pos = pos;
put_fd(descriptor);
return bytesWritten;
}
off_t
_kern_seek(int fd, off_t pos, int seekType)
{
struct file_descriptor *descriptor;
descriptor = get_fd(get_current_io_context(true), fd);
if (!descriptor)
return B_FILE_ERROR;
if (descriptor->ops->fd_seek)
pos = descriptor->ops->fd_seek(descriptor, pos, seekType);
else
pos = ESPIPE;
put_fd(descriptor);
return pos;
}
status_t
_kern_ioctl(int fd, ulong op, void *buffer, size_t length)
{
TRACE(("kern_ioctl: fd %d\n", fd));
return fd_ioctl(true, fd, op, buffer, length);
}
status_t
user_fd_kernel_ioctl(int fd, ulong op, void *buffer, size_t length)
{
TRACE(("user_fd_kernel_ioctl: fd %d\n", fd));
return fd_ioctl(false, fd, op, buffer, length);
}
ssize_t
_kern_read_dir(int fd, struct dirent *buffer, size_t bufferSize, uint32 maxCount)
{
struct file_descriptor *descriptor;
ssize_t retval;
TRACE(("sys_read_dir(fd = %d, buffer = %p, bufferSize = %ld, count = %lu)\n",fd, buffer, bufferSize, maxCount));
descriptor = get_fd(get_current_io_context(true), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (descriptor->ops->fd_read_dir) {
uint32 count = maxCount;
retval = descriptor->ops->fd_read_dir(descriptor, buffer, bufferSize, &count);
if (retval >= 0)
retval = count;
} else
retval = EOPNOTSUPP;
put_fd(descriptor);
return retval;
}
status_t
_kern_rewind_dir(int fd)
{
struct file_descriptor *descriptor;
status_t status;
TRACE(("sys_rewind_dir(fd = %d)\n",fd));
descriptor = get_fd(get_current_io_context(true), fd);
if (descriptor == NULL)
return B_FILE_ERROR;
if (descriptor->ops->fd_rewind_dir)
status = descriptor->ops->fd_rewind_dir(descriptor);
else
status = EOPNOTSUPP;
put_fd(descriptor);
return status;
}
status_t
_kern_close(int fd)
{
return common_close(fd, true);
}
int
_kern_dup(int fd)
{
return dup_fd(fd, true);
}
int
_kern_dup2(int ofd, int nfd)
{
return dup2_fd(ofd, nfd, true);
}