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/*
FUSE: Filesystem in Userspace
Copyright (C) 2001-2007 Miklos Szeredi <miklos@szeredi.hu>
This program can be distributed under the terms of the GNU LGPLv2.
See the file COPYING.LIB.
*/
#ifndef FUSE_H_
#define FUSE_H_
/** @file
*
* This file defines the library interface of FUSE
*
* IMPORTANT: you should define FUSE_USE_VERSION before including this header.
*/
#include "fuse_common.h"
#include <fcntl.h>
#include <time.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/statvfs.h>
#include <sys/uio.h>
#ifdef __cplusplus
extern "C" {
#endif
/* ----------------------------------------------------------- *
* Basic FUSE API *
* ----------------------------------------------------------- */
/** Handle for a FUSE filesystem */
struct fuse;
/**
* Readdir flags, passed to ->readdir()
*/
enum fuse_readdir_flags {
/**
* "Plus" mode.
*
* The kernel wants to prefill the inode cache during readdir. The
* filesystem may honour this by filling in the attributes and setting
* FUSE_FILL_DIR_FLAGS for the filler function. The filesystem may also
* just ignore this flag completely.
*/
FUSE_READDIR_PLUS = (1 << 0),
};
enum fuse_fill_dir_flags {
/**
* "Plus" mode: all file attributes are valid
*
* The attributes are used by the kernel to prefill the inode cache
* during a readdir.
*
* It is okay to set FUSE_FILL_DIR_PLUS if FUSE_READDIR_PLUS is not set
* and vice versa.
*/
FUSE_FILL_DIR_PLUS = (1 << 1),
};
/** Function to add an entry in a readdir() operation
*
* @param buf the buffer passed to the readdir() operation
* @param name the file name of the directory entry
* @param stat file attributes, can be NULL
* @param off offset of the next entry or zero
* @param flags fill flags
* @return 1 if buffer is full, zero otherwise
*/
typedef int (*fuse_fill_dir_t) (void *buf, const char *name,
const struct stat *stbuf, off_t off,
enum fuse_fill_dir_flags flags);
/**
* Configuration of the high-level API
*
* This structure is initialized from the arguments passed to
* fuse_new(), and then passed to the file system's init() handler
* which should ensure that the configuration is compatible with the
* file system implementation.
*/
struct fuse_config {
/**
* If `set_gid` is non-zero, the st_gid attribute of each file
* is overwritten with the value of `gid`.
*/
int set_gid;
unsigned int gid;
/**
* If `set_uid` is non-zero, the st_uid attribute of each file
* is overwritten with the value of `uid`.
*/
int set_uid;
unsigned int uid;
/**
* If `set_mode` is non-zero, the any permissions bits set in
* `umask` are unset in the st_mode attribute of each file.
*/
int set_mode;
unsigned int umask;
/**
* The timeout in seconds for which name lookups will be
* cached.
*/
double entry_timeout;
/**
* The timeout in seconds for which a negative lookup will be
* cached. This means, that if file did not exist (lookup
* retuned ENOENT), the lookup will only be redone after the
* timeout, and the file/directory will be assumed to not
* exist until then. A value of zero means that negative
* lookups are not cached.
*/
double negative_timeout;
/**
* The timeout in seconds for which file/directory attributes
* (as returned by e.g. the `getattr` handler) are cached.
*/
double attr_timeout;
/**
* Allow requests to be interrupted
*/
int intr;
/**
* Specify which signal number to send to the filesystem when
* a request is interrupted. The default is hardcoded to
* USR1.
*/
int intr_signal;
/**
* Normally, FUSE assigns inodes to paths only for as long as
* the kernel is aware of them. With this option inodes are
* instead remembered for at least this many seconds. This
* will require more memory, but may be necessary when using
* applications that make use of inode numbers.
*
* A number of -1 means that inodes will be remembered for the
* entire life-time of the file-system process.
*/
int remember;
/**
* The default behavior is that if an open file is deleted,
* the file is renamed to a hidden file (.fuse_hiddenXXX), and
* only removed when the file is finally released. This
* relieves the filesystem implementation of having to deal
* with this problem. This option disables the hiding
* behavior, and files are removed immediately in an unlink
* operation (or in a rename operation which overwrites an
* existing file).
*
* It is recommended that you not use the hard_remove
* option. When hard_remove is set, the following libc
* functions fail on unlinked files (returning errno of
* ENOENT): read(2), write(2), fsync(2), close(2), f*xattr(2),
* ftruncate(2), fstat(2), fchmod(2), fchown(2)
*/
int hard_remove;
/**
* Honor the st_ino field in the functions getattr() and
* fill_dir(). This value is used to fill in the st_ino field
* in the stat(2), lstat(2), fstat(2) functions and the d_ino
* field in the readdir(2) function. The filesystem does not
* have to guarantee uniqueness, however some applications
* rely on this value being unique for the whole filesystem.
*/
int use_ino;
/**
* If use_ino option is not given, still try to fill in the
* d_ino field in readdir(2). If the name was previously
* looked up, and is still in the cache, the inode number
* found there will be used. Otherwise it will be set to -1.
* If use_ino option is given, this option is ignored.
*/
int readdir_ino;
/**
* This option disables the use of page cache (file content cache)
* in the kernel for this filesystem. This has several affects:
*
* 1. Each read(2) or write(2) system call will initiate one
* or more read or write operations, data will not be
* cached in the kernel.
*
* 2. The return value of the read() and write() system calls
* will correspond to the return values of the read and
* write operations. This is useful for example if the
* file size is not known in advance (before reading it).
*
* Internally, enabling this option causes fuse to set the
* `direct_io` field of `struct fuse_file_info` - overwriting
* any value that was put there by the file system.
*/
int direct_io;
/**
* This option disables flushing the cache of the file
* contents on every open(2). This should only be enabled on
* filesystems, where the file data is never changed
* externally (not through the mounted FUSE filesystem). Thus
* it is not suitable for network filesystems and other
* intermediate filesystems.
*
* NOTE: if this option is not specified (and neither
* direct_io) data is still cached after the open(2), so a
* read(2) system call will not always initiate a read
* operation.
*
* Internally, enabling this option causes fuse to set the
* `keep_cache` field of `struct fuse_file_info` - overwriting
* any value that was put there by the file system.
*/
int kernel_cache;
/**
* This option is an alternative to `kernel_cache`. Instead of
* unconditionally keeping cached data, the cached data is
* invalidated on open(2) if if the modification time or the
* size of the file has changed since it was last opened.
*/
int auto_cache;
/**
* The timeout in seconds for which file attributes are cached
* for the purpose of checking if auto_cache should flush the
* file data on open.
*/
int ac_attr_timeout_set;
double ac_attr_timeout;
/**
* If this option is given the file-system handlers for the
* following operations will not receive path information:
* read, write, flush, release, fsync, readdir, releasedir,
* fsyncdir, lock, ioctl and poll.
*
* For the truncate, getattr, chmod, chown and utimens
* operations the path will be provided only if the struct
* fuse_file_info argument is NULL.
*/
int nullpath_ok;
/**
* The remaining options are used by libfuse internally and
* should not be touched.
*/
int show_help;
char *modules;
int debug;
};
/**
* The file system operations:
*
* Most of these should work very similarly to the well known UNIX
* file system operations. A major exception is that instead of
* returning an error in 'errno', the operation should return the
* negated error value (-errno) directly.
*
* All methods are optional, but some are essential for a useful
* filesystem (e.g. getattr). Open, flush, release, fsync, opendir,
* releasedir, fsyncdir, access, create, truncate, lock, init and
* destroy are special purpose methods, without which a full featured
* filesystem can still be implemented.
*
* In general, all methods are expected to perform any necessary
* permission checking. However, a filesystem may delegate this task
* to the kernel by passing the `default_permissions` mount option to
* `fuse_new()`. In this case, methods will only be called if
* the kernel's permission check has succeeded.
*
* Almost all operations take a path which can be of any length.
*/
struct fuse_operations {
/** Get file attributes.
*
* Similar to stat(). The 'st_dev' and 'st_blksize' fields are
* ignored. The 'st_ino' field is ignored except if the 'use_ino'
* mount option is given.
*
* `fi` will always be NULL if the file is not currenly open, but
* may also be NULL if the file is open.
*/
int (*getattr) (const char *, struct stat *, struct fuse_file_info *fi);
/** Read the target of a symbolic link
*
* The buffer should be filled with a null terminated string. The
* buffer size argument includes the space for the terminating
* null character. If the linkname is too long to fit in the
* buffer, it should be truncated. The return value should be 0
* for success.
*/
int (*readlink) (const char *, char *, size_t);
/** Create a file node
*
* This is called for creation of all non-directory, non-symlink
* nodes. If the filesystem defines a create() method, then for
* regular files that will be called instead.
*/
int (*mknod) (const char *, mode_t, dev_t);
/** Create a directory
*
* Note that the mode argument may not have the type specification
* bits set, i.e. S_ISDIR(mode) can be false. To obtain the
* correct directory type bits use mode|S_IFDIR
* */
int (*mkdir) (const char *, mode_t);
/** Remove a file */
int (*unlink) (const char *);
/** Remove a directory */
int (*rmdir) (const char *);
/** Create a symbolic link */
int (*symlink) (const char *, const char *);
/** Rename a file */
int (*rename) (const char *, const char *, unsigned int);
/** Create a hard link to a file */
int (*link) (const char *, const char *);
/** Change the permission bits of a file
*
* `fi` will always be NULL if the file is not currenly open, but
* may also be NULL if the file is open.
*/
int (*chmod) (const char *, mode_t, struct fuse_file_info *fi);
/** Change the owner and group of a file
*
* `fi` will always be NULL if the file is not currenly open, but
* may also be NULL if the file is open.
*
* Unless FUSE_CAP_HANDLE_KILLPRIV is disabled, this method is
* expected to reset the setuid and setgid bits.
*/
int (*chown) (const char *, uid_t, gid_t, struct fuse_file_info *fi);
/** Change the size of a file
*
* `fi` will always be NULL if the file is not currenly open, but
* may also be NULL if the file is open.
*
* Unless FUSE_CAP_HANDLE_KILLPRIV is disabled, this method is
* expected to reset the setuid and setgid bits.
*/
int (*truncate) (const char *, off_t, struct fuse_file_info *fi);
/** File open operation
*
* No creation (O_CREAT, O_EXCL) and by default also no
* truncation (O_TRUNC) flags will be passed to open(). If an
* application specifies O_TRUNC, fuse first calls truncate()
* and then open(). Only if 'atomic_o_trunc' has been
* specified and kernel version is 2.6.24 or later, O_TRUNC is
* passed on to open.
*
* Unless the 'default_permissions' mount option is given,
* open should check if the operation is permitted for the
* given flags. Optionally open may also return an arbitrary
* filehandle in the fuse_file_info structure, which will be
* passed to all file operations.
*/
int (*open) (const char *, struct fuse_file_info *);
/** Read data from an open file
*
* Read should return exactly the number of bytes requested except
* on EOF or error, otherwise the rest of the data will be
* substituted with zeroes. An exception to this is when the
* 'direct_io' mount option is specified, in which case the return
* value of the read system call will reflect the return value of
* this operation.
*/
int (*read) (const char *, char *, size_t, off_t,
struct fuse_file_info *);
/** Write data to an open file
*
* Write should return exactly the number of bytes requested
* except on error. An exception to this is when the 'direct_io'
* mount option is specified (see read operation).
*
* Unless FUSE_CAP_HANDLE_KILLPRIV is disabled, this method is
* expected to reset the setuid and setgid bits.
*/
int (*write) (const char *, const char *, size_t, off_t,
struct fuse_file_info *);
/** Get file system statistics
*
* The 'f_favail', 'f_fsid' and 'f_flag' fields are ignored
*/
int (*statfs) (const char *, struct statvfs *);
/** Possibly flush cached data
*
* BIG NOTE: This is not equivalent to fsync(). It's not a
* request to sync dirty data.
*
* Flush is called on each close() of a file descriptor. So if a
* filesystem wants to return write errors in close() and the file
* has cached dirty data, this is a good place to write back data
* and return any errors. Since many applications ignore close()
* errors this is not always useful.
*
* NOTE: The flush() method may be called more than once for each
* open(). This happens if more than one file descriptor refers
* to an opened file due to dup(), dup2() or fork() calls. It is
* not possible to determine if a flush is final, so each flush
* should be treated equally. Multiple write-flush sequences are
* relatively rare, so this shouldn't be a problem.
*
* Filesystems shouldn't assume that flush will always be called
* after some writes, or that if will be called at all.
*/
int (*flush) (const char *, struct fuse_file_info *);
/** Release an open file
*
* Release is called when there are no more references to an open
* file: all file descriptors are closed and all memory mappings
* are unmapped.
*
* For every open() call there will be exactly one release() call
* with the same flags and file descriptor. It is possible to
* have a file opened more than once, in which case only the last
* release will mean, that no more reads/writes will happen on the
* file. The return value of release is ignored.
*/
int (*release) (const char *, struct fuse_file_info *);
/** Synchronize file contents
*
* If the datasync parameter is non-zero, then only the user data
* should be flushed, not the meta data.
*/
int (*fsync) (const char *, int, struct fuse_file_info *);
/** Set extended attributes */
int (*setxattr) (const char *, const char *, const char *, size_t, int);
/** Get extended attributes */
int (*getxattr) (const char *, const char *, char *, size_t);
/** List extended attributes */
int (*listxattr) (const char *, char *, size_t);
/** Remove extended attributes */
int (*removexattr) (const char *, const char *);
/** Open directory
*
* Unless the 'default_permissions' mount option is given,
* this method should check if opendir is permitted for this
* directory. Optionally opendir may also return an arbitrary
* filehandle in the fuse_file_info structure, which will be
* passed to readdir, closedir and fsyncdir.
*/
int (*opendir) (const char *, struct fuse_file_info *);
/** Read directory
*
* The filesystem may choose between two modes of operation:
*
* 1) The readdir implementation ignores the offset parameter, and
* passes zero to the filler function's offset. The filler
* function will not return '1' (unless an error happens), so the
* whole directory is read in a single readdir operation.
*
* 2) The readdir implementation keeps track of the offsets of the
* directory entries. It uses the offset parameter and always
* passes non-zero offset to the filler function. When the buffer
* is full (or an error happens) the filler function will return
* '1'.
*/
int (*readdir) (const char *, void *, fuse_fill_dir_t, off_t,
struct fuse_file_info *, enum fuse_readdir_flags);
/** Release directory
*/
int (*releasedir) (const char *, struct fuse_file_info *);
/** Synchronize directory contents
*
* If the datasync parameter is non-zero, then only the user data
* should be flushed, not the meta data
*/
int (*fsyncdir) (const char *, int, struct fuse_file_info *);
/**
* Initialize filesystem
*
* The return value will passed in the private_data field of
* fuse_context to all file operations and as a parameter to the
* destroy() method.
*/
void *(*init) (struct fuse_conn_info *conn,
struct fuse_config *cfg);
/**
* Clean up filesystem
*
* Called on filesystem exit.
*/
void (*destroy) (void *);
/**
* Check file access permissions
*
* This will be called for the access() system call. If the
* 'default_permissions' mount option is given, this method is not
* called.
*
* This method is not called under Linux kernel versions 2.4.x
*/
int (*access) (const char *, int);
/**
* Create and open a file
*
* If the file does not exist, first create it with the specified
* mode, and then open it.
*
* If this method is not implemented or under Linux kernel
* versions earlier than 2.6.15, the mknod() and open() methods
* will be called instead.
*/
int (*create) (const char *, mode_t, struct fuse_file_info *);
/**
* Perform POSIX file locking operation
*
* The cmd argument will be either F_GETLK, F_SETLK or F_SETLKW.
*
* For the meaning of fields in 'struct flock' see the man page
* for fcntl(2). The l_whence field will always be set to
* SEEK_SET.
*
* For checking lock ownership, the 'fuse_file_info->owner'
* argument must be used.
*
* For F_GETLK operation, the library will first check currently
* held locks, and if a conflicting lock is found it will return
* information without calling this method. This ensures, that
* for local locks the l_pid field is correctly filled in. The
* results may not be accurate in case of race conditions and in
* the presence of hard links, but it's unlikely that an
* application would rely on accurate GETLK results in these
* cases. If a conflicting lock is not found, this method will be
* called, and the filesystem may fill out l_pid by a meaningful
* value, or it may leave this field zero.
*
* For F_SETLK and F_SETLKW the l_pid field will be set to the pid
* of the process performing the locking operation.
*
* Note: if this method is not implemented, the kernel will still
* allow file locking to work locally. Hence it is only
* interesting for network filesystems and similar.
*/
int (*lock) (const char *, struct fuse_file_info *, int cmd,
struct flock *);
/**
* Change the access and modification times of a file with
* nanosecond resolution
*
* This supersedes the old utime() interface. New applications
* should use this.
*
* `fi` will always be NULL if the file is not currenly open, but
* may also be NULL if the file is open.
*
* See the utimensat(2) man page for details.
*/
int (*utimens) (const char *, const struct timespec tv[2],
struct fuse_file_info *fi);
/**
* Map block index within file to block index within device
*
* Note: This makes sense only for block device backed filesystems
* mounted with the 'blkdev' option
*/
int (*bmap) (const char *, size_t blocksize, uint64_t *idx);
/**
* Ioctl
*
* flags will have FUSE_IOCTL_COMPAT set for 32bit ioctls in
* 64bit environment. The size and direction of data is
* determined by _IOC_*() decoding of cmd. For _IOC_NONE,
* data will be NULL, for _IOC_WRITE data is out area, for
* _IOC_READ in area and if both are set in/out area. In all
* non-NULL cases, the area is of _IOC_SIZE(cmd) bytes.
*
* If flags has FUSE_IOCTL_DIR then the fuse_file_info refers to a
* directory file handle.
*/
int (*ioctl) (const char *, int cmd, void *arg,
struct fuse_file_info *, unsigned int flags, void *data);
/**
* Poll for IO readiness events
*
* Note: If ph is non-NULL, the client should notify
* when IO readiness events occur by calling
* fuse_notify_poll() with the specified ph.
*
* Regardless of the number of times poll with a non-NULL ph
* is received, single notification is enough to clear all.
* Notifying more times incurs overhead but doesn't harm
* correctness.
*
* The callee is responsible for destroying ph with
* fuse_pollhandle_destroy() when no longer in use.
*/
int (*poll) (const char *, struct fuse_file_info *,
struct fuse_pollhandle *ph, unsigned *reventsp);
/** Write contents of buffer to an open file
*
* Similar to the write() method, but data is supplied in a
* generic buffer. Use fuse_buf_copy() to transfer data to
* the destination.
*
* Unless FUSE_CAP_HANDLE_KILLPRIV is disabled, this method is
* expected to reset the setuid and setgid bits.
*/
int (*write_buf) (const char *, struct fuse_bufvec *buf, off_t off,
struct fuse_file_info *);
/** Store data from an open file in a buffer
*
* Similar to the read() method, but data is stored and
* returned in a generic buffer.
*
* No actual copying of data has to take place, the source
* file descriptor may simply be stored in the buffer for
* later data transfer.
*
* The buffer must be allocated dynamically and stored at the
* location pointed to by bufp. If the buffer contains memory
* regions, they too must be allocated using malloc(). The
* allocated memory will be freed by the caller.
*/
int (*read_buf) (const char *, struct fuse_bufvec **bufp,
size_t size, off_t off, struct fuse_file_info *);
/**
* Perform BSD file locking operation
*
* The op argument will be either LOCK_SH, LOCK_EX or LOCK_UN
*
* Nonblocking requests will be indicated by ORing LOCK_NB to
* the above operations
*
* For more information see the flock(2) manual page.
*
* Additionally fi->owner will be set to a value unique to
* this open file. This same value will be supplied to
* ->release() when the file is released.
*
* Note: if this method is not implemented, the kernel will still
* allow file locking to work locally. Hence it is only
* interesting for network filesystems and similar.
*/
int (*flock) (const char *, struct fuse_file_info *, int op);
/**
* Allocates space for an open file
*
* This function ensures that required space is allocated for specified
* file. If this function returns success then any subsequent write
* request to specified range is guaranteed not to fail because of lack
* of space on the file system media.
*/
int (*fallocate) (const char *, int, off_t, off_t,
struct fuse_file_info *);
};
/** Extra context that may be needed by some filesystems
*
* The uid, gid and pid fields are not filled in case of a writepage
* operation.
*/
struct fuse_context {
/** Pointer to the fuse object */
struct fuse *fuse;
/** User ID of the calling process */
uid_t uid;
/** Group ID of the calling process */
gid_t gid;
/** Thread ID of the calling process */
pid_t pid;
/** Private filesystem data */
void *private_data;
/** Umask of the calling process */
mode_t umask;
};
/**
* Main function of FUSE.
*
* This is for the lazy. This is all that has to be called from the
* main() function.
*
* This function does the following:
* - parses command line options, and handles --help and
* --version
* - installs signal handlers for INT, HUP, TERM and PIPE
* - registers an exit handler to unmount the filesystem on program exit
* - creates a fuse handle
* - registers the operations
* - calls either the single-threaded or the multi-threaded event loop
*
* Most file systems will have to parse some file-system specific
* arguments before calling this function. It is recommended to do
* this with fuse_opt_parse() and a processing function that passes
* through any unknown options (this can also be achieved by just
* passing NULL as the processing function). That way, the remaining
* options can be passed directly to fuse_main().
*
* fuse_main() accepts all options that can be passed to
* fuse_parse_cmdline(), fuse_new(), or fuse_session_new().
*
* Option parsing skips argv[0], which is assumed to contain the
* program name. This element must always be present and is used to
* construct a basic ``usage: `` message for the --help
* output. argv[0] may also be set to the empty string. In this case
* the usage message is suppressed. This can be used by file systems
* to print their own usage line first. See hello.c for an example of
* how to do this.
*
* Note: this is currently implemented as a macro.
*
* @param argc the argument counter passed to the main() function
* @param argv the argument vector passed to the main() function
* @param op the file system operation
* @param user_data user data supplied in the context during the init() method
* @return 0 on success, nonzero on failure
*
* Example usage, see hello.c
*/
/*
int fuse_main(int argc, char *argv[], const struct fuse_operations *op,
void *user_data);
*/
#define fuse_main(argc, argv, op, user_data) \
fuse_main_real(argc, argv, op, sizeof(*(op)), user_data)
/* ----------------------------------------------------------- *
* More detailed API *
* ----------------------------------------------------------- */
/**
* Create a new FUSE filesystem.
*
* This function accepts most file-system independent mount options
* (like context, nodev, ro - see mount(8)), as well as the
* FUSE-specific mount options from mount.fuse(8).
*
* If the --help option is specified, the function writes a help text
* to stdout and returns NULL.
*
* Option parsing skips argv[0], which is assumed to contain the
* program name. This element must always be present and is used to
* construct a basic ``usage: `` message for the --help output. If
* argv[0] is set to the empty string, no usage message is included in
* the --help output.
*
* If an unknown option is passed in, an error message is written to
* stderr and the function returns NULL.
*
* @param args argument vector
* @param op the filesystem operations
* @param op_size the size of the fuse_operations structure
* @param user_data user data supplied in the context during the init() method
* @return the created FUSE handle
*/
struct fuse *fuse_new(struct fuse_args *args, const struct fuse_operations *op,
size_t op_size, void *user_data);
/**
* Mount a FUSE file system.
*
* @param mountpoint the mount point path
* @param f the FUSE handle
*
* @return 0 on success, -1 on failure.
**/
int fuse_mount(struct fuse *f, const char *mountpoint);
/**
* Unmount a FUSE file system.
*
* See fuse_session_unmount() for additional information.
*
* @param f the FUSE handle
**/
void fuse_unmount(struct fuse *f);
/**
* Destroy the FUSE handle.
*
* NOTE: This function does not unmount the filesystem. If this is
* needed, call fuse_unmount() before calling this function.
*
* @param f the FUSE handle
*/
void fuse_destroy(struct fuse *f);
/**
* FUSE event loop.
*
* Requests from the kernel are processed, and the appropriate
* operations are called.
*
* For a description of the return value and the conditions when the
* event loop exits, refer to the documentation of
* fuse_session_loop().
*
* @param f the FUSE handle
* @return see fuse_session_loop()
*
* See also: fuse_loop_mt()
*/
int fuse_loop(struct fuse *f);
/**
* Flag session as terminated
*
* This function will cause any running event loops to exit on
* the next opportunity.
*
* @param f the FUSE handle
*/
void fuse_exit(struct fuse *f);
/**
* FUSE event loop with multiple threads
*
* Requests from the kernel are processed, and the appropriate
* operations are called. Request are processed in parallel by
* distributing them between multiple threads.
*
* For a description of the return value and the conditions when the
* event loop exits, refer to the documentation of
* fuse_session_loop().
*
* Note: using fuse_loop() instead of fuse_loop_mt() means you are running in
* single-threaded mode, and that you will not have to worry about reentrancy,
* though you will have to worry about recursive lookups. In single-threaded
* mode, FUSE will wait for one callback to return before calling another.
*
* Enabling multiple threads, by using fuse_loop_mt(), will cause FUSE to make
* multiple simultaneous calls into the various callback functions given by your
* fuse_operations record.
*
* If you are using multiple threads, you can enjoy all the parallel execution
* and interactive response benefits of threads, and you get to enjoy all the
* benefits of race conditions and locking bugs, too. Ensure that any code used
* in the callback function of fuse_operations is also thread-safe.
*
* @param f the FUSE handle
* @param clone_fd whether to use separate device fds for each thread
* (may increase performance)
* @return see fuse_session_loop()
*
* See also: fuse_loop()
*/
int fuse_loop_mt(struct fuse *f, int clone_fd);
/**
* Get the current context
*
* The context is only valid for the duration of a filesystem
* operation, and thus must not be stored and used later.
*
* @return the context
*/
struct fuse_context *fuse_get_context(void);
/**
* Get the current supplementary group IDs for the current request
*
* Similar to the getgroups(2) system call, except the return value is
* always the total number of group IDs, even if it is larger than the
* specified size.
*
* The current fuse kernel module in linux (as of 2.6.30) doesn't pass
* the group list to userspace, hence this function needs to parse
* "/proc/$TID/task/$TID/status" to get the group IDs.
*
* This feature may not be supported on all operating systems. In
* such a case this function will return -ENOSYS.
*
* @param size size of given array
* @param list array of group IDs to be filled in
* @return the total number of supplementary group IDs or -errno on failure
*/
int fuse_getgroups(int size, gid_t list[]);
/**
* Check if the current request has already been interrupted
*
* @return 1 if the request has been interrupted, 0 otherwise
*/
int fuse_interrupted(void);
/**
* The real main function
*
* Do not call this directly, use fuse_main()
*/
int fuse_main_real(int argc, char *argv[], const struct fuse_operations *op,
size_t op_size, void *user_data);
/**
* Start the cleanup thread when using option "remember".
*
* This is done automatically by fuse_loop_mt()
* @param fuse struct fuse pointer for fuse instance
* @return 0 on success and -1 on error
*/
int fuse_start_cleanup_thread(struct fuse *fuse);
/**
* Stop the cleanup thread when using option "remember".
*
* This is done automatically by fuse_loop_mt()
* @param fuse struct fuse pointer for fuse instance
*/
void fuse_stop_cleanup_thread(struct fuse *fuse);
/**
* Iterate over cache removing stale entries
* use in conjunction with "-oremember"
*
* NOTE: This is already done for the standard sessions
*
* @param fuse struct fuse pointer for fuse instance
* @return the number of seconds until the next cleanup
*/
int fuse_clean_cache(struct fuse *fuse);
/*
* Stacking API
*/
/**
* Fuse filesystem object
*
* This is opaque object represents a filesystem layer
*/
struct fuse_fs;
/*
* These functions call the relevant filesystem operation, and return
* the result.
*
* If the operation is not defined, they return -ENOSYS, with the
* exception of fuse_fs_open, fuse_fs_release, fuse_fs_opendir,
* fuse_fs_releasedir and fuse_fs_statfs, which return 0.
*/
int fuse_fs_getattr(struct fuse_fs *fs, const char *path, struct stat *buf,
struct fuse_file_info *fi);
int fuse_fs_rename(struct fuse_fs *fs, const char *oldpath,
const char *newpath, unsigned int flags);
int fuse_fs_unlink(struct fuse_fs *fs, const char *path);
int fuse_fs_rmdir(struct fuse_fs *fs, const char *path);
int fuse_fs_symlink(struct fuse_fs *fs, const char *linkname,
const char *path);
int fuse_fs_link(struct fuse_fs *fs, const char *oldpath, const char *newpath);
int fuse_fs_release(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi);
int fuse_fs_open(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi);
int fuse_fs_read(struct fuse_fs *fs, const char *path, char *buf, size_t size,
off_t off, struct fuse_file_info *fi);
int fuse_fs_read_buf(struct fuse_fs *fs, const char *path,
struct fuse_bufvec **bufp, size_t size, off_t off,
struct fuse_file_info *fi);
int fuse_fs_write(struct fuse_fs *fs, const char *path, const char *buf,
size_t size, off_t off, struct fuse_file_info *fi);
int fuse_fs_write_buf(struct fuse_fs *fs, const char *path,
struct fuse_bufvec *buf, off_t off,
struct fuse_file_info *fi);
int fuse_fs_fsync(struct fuse_fs *fs, const char *path, int datasync,
struct fuse_file_info *fi);
int fuse_fs_flush(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi);
int fuse_fs_statfs(struct fuse_fs *fs, const char *path, struct statvfs *buf);
int fuse_fs_opendir(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi);
int fuse_fs_readdir(struct fuse_fs *fs, const char *path, void *buf,
fuse_fill_dir_t filler, off_t off,
struct fuse_file_info *fi, enum fuse_readdir_flags flags);
int fuse_fs_fsyncdir(struct fuse_fs *fs, const char *path, int datasync,
struct fuse_file_info *fi);
int fuse_fs_releasedir(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi);
int fuse_fs_create(struct fuse_fs *fs, const char *path, mode_t mode,
struct fuse_file_info *fi);
int fuse_fs_lock(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi, int cmd, struct flock *lock);
int fuse_fs_flock(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi, int op);
int fuse_fs_chmod(struct fuse_fs *fs, const char *path, mode_t mode,
struct fuse_file_info *fi);
int fuse_fs_chown(struct fuse_fs *fs, const char *path, uid_t uid, gid_t gid,
struct fuse_file_info *fi);
int fuse_fs_truncate(struct fuse_fs *fs, const char *path, off_t size,
struct fuse_file_info *fi);
int fuse_fs_utimens(struct fuse_fs *fs, const char *path,
const struct timespec tv[2], struct fuse_file_info *fi);
int fuse_fs_access(struct fuse_fs *fs, const char *path, int mask);
int fuse_fs_readlink(struct fuse_fs *fs, const char *path, char *buf,
size_t len);
int fuse_fs_mknod(struct fuse_fs *fs, const char *path, mode_t mode,
dev_t rdev);
int fuse_fs_mkdir(struct fuse_fs *fs, const char *path, mode_t mode);
int fuse_fs_setxattr(struct fuse_fs *fs, const char *path, const char *name,
const char *value, size_t size, int flags);
int fuse_fs_getxattr(struct fuse_fs *fs, const char *path, const char *name,
char *value, size_t size);
int fuse_fs_listxattr(struct fuse_fs *fs, const char *path, char *list,
size_t size);
int fuse_fs_removexattr(struct fuse_fs *fs, const char *path,
const char *name);
int fuse_fs_bmap(struct fuse_fs *fs, const char *path, size_t blocksize,
uint64_t *idx);
int fuse_fs_ioctl(struct fuse_fs *fs, const char *path, int cmd, void *arg,
struct fuse_file_info *fi, unsigned int flags, void *data);
int fuse_fs_poll(struct fuse_fs *fs, const char *path,
struct fuse_file_info *fi, struct fuse_pollhandle *ph,
unsigned *reventsp);
int fuse_fs_fallocate(struct fuse_fs *fs, const char *path, int mode,
off_t offset, off_t length, struct fuse_file_info *fi);
void fuse_fs_init(struct fuse_fs *fs, struct fuse_conn_info *conn,
struct fuse_config *cfg);
void fuse_fs_destroy(struct fuse_fs *fs);
int fuse_notify_poll(struct fuse_pollhandle *ph);
/**
* Create a new fuse filesystem object
*
* This is usually called from the factory of a fuse module to create
* a new instance of a filesystem.
*
* @param op the filesystem operations
* @param op_size the size of the fuse_operations structure
* @param user_data user data supplied in the context during the init() method
* @return a new filesystem object
*/
struct fuse_fs *fuse_fs_new(const struct fuse_operations *op, size_t op_size,
void *user_data);
/**
* Factory for creating filesystem objects
*
* The function may use and remove options from 'args' that belong
* to this module.
*
* For now the 'fs' vector always contains exactly one filesystem.
* This is the filesystem which will be below the newly created
* filesystem in the stack.
*
* @param args the command line arguments
* @param fs NULL terminated filesystem object vector
* @return the new filesystem object
*/
typedef struct fuse_fs *(*fuse_module_factory_t)(struct fuse_args *args,
struct fuse_fs *fs[]);
/**
* Register filesystem module
*
* If the "-omodules=*name*_:..." option is present, filesystem
* objects are created and pushed onto the stack with the *factory_*
* function.
*
* @param name_ the name of this filesystem module
* @param factory_ the factory function for this filesystem module
*/
#define FUSE_REGISTER_MODULE(name_, factory_) \
fuse_module_factory_t fuse_module_ ## name_ ## _factory = factory_;
/** Get session from fuse object */
struct fuse_session *fuse_get_session(struct fuse *f);
#ifdef __cplusplus
}
#endif
#endif /* FUSE_H_ */