path: root/libdiskfs/diskfs.h

/* Definitions for fileserver helper functions

   Copyright (C) 1994, 1995, 1996, 1997, 1998, 1999, 2001, 2002, 2007, 2008,
   2009, 2013 Free Software Foundation, Inc.

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License as
   published by the Free Software Foundation; either version 2, or (at
   your option) any later version.

   This program is distributed in the hope that it will be useful, but
   WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */

#ifndef _HURD_DISKFS
#define _HURD_DISKFS

#include <assert-backtrace.h>
#include <unistd.h>
#include <pthread.h>
#include <hurd/ports.h>
#include <hurd/fshelp.h>
#include <hurd/ihash.h>
#include <hurd/iohelp.h>
#include <idvec.h>
#include <features.h>
#include <refcount.h>

#ifdef DISKFS_DEFINE_EXTERN_INLINE
#define DISKFS_EXTERN_INLINE
#else
#define DISKFS_EXTERN_INLINE __extern_inline
#endif

/* Each user port referring to a file points to one of these
   (with the aid of the ports library).  */
struct protid
{
  struct port_info pi;		/* libports info block */

  /* User identification */
  struct iouser *user;

  /* Object this refers to */
  struct peropen *po;

  /* Shared memory I/O information.  */
  memory_object_t shared_object;
  struct shared_io *mapped;
};

/* One of these is created for each node opened by dir_lookup. */
struct peropen
{
  loff_t filepointer;
  int lock_status;
  refcount_t refcnt;
  int openstat;

  struct node *np;

  /* The parent of the translator's root node.  */
  mach_port_t root_parent;

  /* If this node is in a shadow tree, the parent of its root.  */
  mach_port_t shadow_root_parent;
  /* If in a shadow tree, its root node in this translator.  */
  struct node *shadow_root;

  /* Path relative to the root of the translator. */
  char *path;
};

/* A unique one of these exists for each node currently in use (and
   possibly for some not currently in use, but with links) in the
   filesystem.  */
struct node
{
  /* The slot we occupy in the node cache.  */
  hurd_ihash_locp_t slot;

  struct disknode *dn;

  io_statbuf_t dn_stat;

  /* Flags.  */
  unsigned int

  /* Stat has been modified if one of the following four fields
     is nonzero.  Also, if one of the dn_set_?time fields is nonzero,
     the appropriate dn_stat.st_?tim field needs to be updated. */
    dn_set_ctime:1,
    dn_set_atime:1,
    dn_set_mtime:1,
    dn_stat_dirty:1,

  /* Indicate whether the author is tracking the uid because the
     on-disk file format does not encode a separate author.  */
    author_tracks_uid:1;

  pthread_mutex_t lock;

  refcounts_t refcounts;

  mach_port_t sockaddr;		/* address for S_IFSOCK shortcut */

  int owner;

  struct transbox transbox;

  struct lock_box userlock;

  struct conch conch;

  struct modreq *dirmod_reqs;
  unsigned int dirmod_tick;

  struct modreq *filemod_reqs;
  unsigned int filemod_tick;

  loff_t allocsize;

  ino64_t cache_id;
};

struct diskfs_control
{
  struct port_info pi;
};

struct bootinfo
{
  struct port_info pi;
};

/* Possibly lookup types for diskfs_lookup call */
enum lookup_type
{
  LOOKUP,
  CREATE,
  REMOVE,
  RENAME,
};

/* Pending directory and file modification request */
struct modreq
{
  mach_port_t port;
  struct modreq *next;
};


/* Special flag for diskfs_lookup. */
#define SPEC_DOTDOT 0x10000000

struct argp;			/* opaque in this file */
struct argp_child;		/* opaque in this file */
struct store;			/* opaque in this file */
struct store_parsed;		/* opaque in this file */

/* Declarations of variables the library sets.  */

extern mach_port_t diskfs_default_pager; /* send right */
extern auth_t diskfs_auth_server_port; /* send right */

/* The io_identity identity port for the filesystem. */
extern mach_port_t diskfs_fsys_identity;

/* The command line diskfs was started, set by the default argument parser.
   If you don't use it, set this yourself.  This is only used for bootstrap
   file systems, to give the procserver.  */
extern char **diskfs_argv;

/* When this is a bootstrap filesystem, the multiboot kernel command
   line passed from the kernel.  If not a bootstrap filesystem, it is
   0.  As such, it can be used to distinguish between the two cases.
   Note: this is only valid after the arguments have been parsed by,
   for example, diskfs_init_main.  */
extern const char *diskfs_boot_command_line;
#define diskfs_boot_filesystem()	(diskfs_boot_command_line != 0)

/* When this is a bootstrap filesystem, nonzero if starting each bootstrap
   program should pause for a keystroke, for debugging purposes.  */
extern int _diskfs_boot_pause;

/* Name of the init program run when this is a bootstrap filesystem.  */
extern const char *diskfs_boot_init_program;

/* Hold this lock while do fsys level operations.  Innocuous users can just
   hold a reader lock, and anyone who's going to do nasty things that would
   screw anyone else should hold a writer lock.  */
extern pthread_rwlock_t diskfs_fsys_lock;

extern volatile struct mapped_time_value *diskfs_mtime;

/* True iff we should do every operation synchronously.  It
   is the format-specific code's responsibility to keep allocation
   information permanently in sync if this is set; the rest will
   be done by format independent code. */
extern int diskfs_synchronous;

extern int pager_port_type;

/* Whether the filesystem is currently writable or not. */
extern int diskfs_readonly;


struct pager;

/* Port classes we manage */
extern struct port_class *diskfs_protid_class;
extern struct port_class *diskfs_control_class;
extern struct port_class *diskfs_execboot_class;
extern struct port_class *diskfs_shutdown_notification_class;

extern struct port_bucket *diskfs_port_bucket;



/* Declarations of things the user must or may define.  */

/* The user must define this type.  This should hold information
   between calls to diskfs_lookup and diskfs_dir{enter,rewrite,rename}
   so that those calls work as described below.  */
struct dirstat;

/* The user must define this variable; it should be the size in bytes
   of a struct dirstat. */
extern const size_t diskfs_dirstat_size;

/* The user must define this variable; it is the maximum number of
   links to any one file.  The implementation of dir_rename does not know
   how to succeed if this is only one; on such formats you need to
   reimplement dir_rename yourself.  */
extern int diskfs_link_max;

/* The user must define this variable; it is the maximum length of
   a single pathname component (i.e. file name within directory).
   The filesystem code does not use this for anything, but it is
   returned to user queries for _PC_NAME_MAX.  */
extern int diskfs_name_max;

/* The user must define this variable; it is the maximum number of
   symlinks to be traversed within a single call to dir_lookup.
   If this is exceeded, dir_lookup will return ELOOP.  */
extern int diskfs_maxsymlinks;

/* This variable is defined by diskfs; the user should set it if
   the filesystem media cannot be made writeable. */
extern int diskfs_hard_readonly;

/* The user must define this variable.  Set this to be the node
   of root of the filesystem.  */
extern struct node *diskfs_root_node;

/* The user must define this variable.  Set this to the name of the
   filesystem server. */
extern char *diskfs_server_name;

/* The user must define this variables.  Set this to be the server
   version number.  */
extern char *diskfs_server_version;

/* The user may define this variable.  Set this to be any additional
   version specification that should be printed for --version. */
extern char *diskfs_extra_version;

/* The user may define this variable.  This should be nonzero iff the
   filesystem format supports shortcutting symlink translation.
   The library guarantees that users will not be able to read or write
   the contents of the node directly, and the library will only do so
   if the symlink hook functions return EINVAL or are not defined.
   The library knows that the dn_stat.st_size field is the length of
   the symlink, even if the hook functions are used. */
int diskfs_shortcut_symlink;

/* The user may define this variable.  This should be nonzero iff the
   filesystem format supports shortcutting chrdev translation.  */
int diskfs_shortcut_chrdev;

/* The user may define this variable.  This should be nonzero iff the
   filesystem format supports shortcutting blkdev translation.  */
int diskfs_shortcut_blkdev;

/* The user may define this variable.  This should be nonzero iff the
   filesystem format supports shortcutting fifo translation.  */
int diskfs_shortcut_fifo;

/* The user may define this variable.  This should be nonzero iff the
   filesystem format supports shortcutting ifsock translation. */
int diskfs_shortcut_ifsock;

/* The user may define this variable, otherwise it has a default value of 30.
   diskfs_set_sync_interval is called with this value when the first diskfs
   thread is started up (in diskfs_spawn_first_thread).   */
extern int diskfs_default_sync_interval;

/* The user must define this variable, which should be a string that somehow
   identifies the particular disk this filesystem is interpreting.  It is
   generally only used to print messages or to distinguish instances of the
   same filesystem type from one another.  If this filesystem accesses no
   external media, then define this to be 0.  */
extern char *diskfs_disk_name;

/* The user must define this function.  Set *STATFSBUF with
   appropriate values to reflect the current state of the filesystem.
   The buffer will be initialized to all zeros by the caller;
   the caller will set f_namelen to diskfs_name_max.  */
error_t diskfs_set_statfs (fsys_statfsbuf_t *statfsbuf);

/* The user must define this function.  Lookup in directory DP (which
   is locked) the name NAME.  TYPE will either be LOOKUP, CREATE,
   RENAME, or REMOVE.  CRED identifies the user making the call.

   If the name is found, return zero, and (if NP is nonzero) set *NP
   to point to the node for it, locked.  If the name is not found,
   return ENOENT, and (if NP is nonzero) set *NP to zero.  If NP is
   zero, then the node found must not be locked, even transitorily.
   Lookups for REMOVE and RENAME (which must often check permissions
   on the node being found) will always set NP.

   If DS is nonzero then:
     For LOOKUP: set *DS to be ignored by diskfs_drop_dirstat.
     For CREATE: on success, set *DS to be ignored by diskfs_drop_dirstat.
                 on failure, set *DS for a future call to diskfs_direnter.
     For RENAME: on success, set *DS for a future call to diskfs_dirrewrite.
                 on failure, set *DS for a future call to diskfs_direnter.
     For REMOVE: on success, set *DS for a future call to diskfs_dirremove.
                 on failure, set *DS to be ignored by diskfs_drop_dirstat.
   The caller of this function guarantees that if DS is nonzero, then
   either the appropriate call listed above or diskfs_drop_dirstat will
   be called with DS before the directory DP is unlocked, and guarantees
   that no lookup calls will be made on this directory between this
   lookup and the use (or descruction) of *DS.

   If you use the library's versions of diskfs_rename_dir,
   diskfs_clear_directory, and diskfs_init_dir, then lookups for `..'
   might have the flag SPEC_DOTDOT or'd in.  This has the following special
   meaning:
   For LOOKUP: DP should be unlocked and its reference dropped before
               returning.
   For RENAME and REMOVE: The node being found (*NP) is already held
               locked, so don't lock it or add a reference to it.
   (SPEC_DOTDOT will not be given with CREATE.)

   Return ENOENT if NAME isn't in the directory.
   Return EAGAIN if NAME refers to the `..' of this filesystem's root.
   Return EIO if appropriate.
*/
error_t diskfs_lookup_hard (struct node *dp,
			    const char *name, enum lookup_type type,
			    struct node **np, struct dirstat *ds,
			    struct protid *cred);

/* The user must define this function.  Add NP to directory DP
   under the name NAME.  This will only be called after an
   unsuccessful call to diskfs_lookup of type CREATE or RENAME; DP
   has been locked continuously since that call and DS is as that call
   set it, NP is locked.   CRED identifies the user responsible
   for the call (to be used only to validate directory growth). */
error_t diskfs_direnter_hard (struct node *dp, const char *name,
			      struct node *np, struct dirstat *ds,
			      struct protid *cred);

/* The user must define this function.  This will only be called after
   a successful call to diskfs_lookup of type RENAME; this call should change
   the name found in directory DP to point to node NP instead of its previous
   referent.  DP has been locked continuously since the call to diskfs_lookup
   and DS is as that call set it; NP is locked.  */
error_t diskfs_dirrewrite_hard (struct node *dp, struct node *np,
				struct dirstat *ds);

/* The user must define this function.  This will only be called after a
   successful call to diskfs_lookup of type REMOVE; this call should remove
   the name found from the directory DS.  DP has been locked continuously since
   the call to diskfs_lookup and DS is as that call set it.  */
error_t diskfs_dirremove_hard (struct node *dp, struct dirstat *ds);

/* The user must define this function.  Initialize DS such that
   diskfs_drop_dirstat will ignore it. */
void diskfs_null_dirstat (struct dirstat *ds);

/* The user must define this function.  DS has been set by a previous
   call to diskfs_lookup on directory DP; this function is
   guaranteed to be called if none of
   diskfs_dir{enter,rename,rewrite} is, and should free any state
   retained by a struct dirstat.  DP has been locked continuously since
   the call to diskfs_lookup.  */
error_t diskfs_drop_dirstat (struct node *dp, struct dirstat *ds);

/* The user must define this function.  Return N directory entries
   starting at ENTRY from locked directory node DP.  Fill *DATA with
   the entries; that pointer currently points to *DATACNT bytes.  If
   it isn't big enough, vm_allocate into *DATA.  Set *DATACNT with the
   total size used.  Fill AMT with the number of entries copied.
   Regardless, never copy more than BUFSIZ bytes.  If BUFSIZ is 0,
   then there is no limit on *DATACNT; if N is -1, then there is no limit
   on AMT. */
error_t diskfs_get_directs (struct node *dp, int entry, int n,
			    char **data, size_t *datacnt,
			    vm_size_t bufsiz, int *amt);

/* The user must define this function.  For locked node NP (for which
   diskfs_node_translated is true) look up the name of its translator.
   Store the name into newly malloced storage; set *NAMELEN to the
   total length.  */
error_t diskfs_get_translator (struct node *np, char **namep, u_int *namelen);

/* The user must define this function.  For locked node NP, set
   the name of the translating program to be NAME, length NAMELEN.  CRED
   identifies the user responsible for the call.  */
error_t diskfs_set_translator (struct node *np,
			       const char *name, u_int namelen,
			       struct protid *cred);

/* The user must define this function.  Truncate locked node NP to be SIZE
   bytes long.  (If NP is already less than or equal to SIZE bytes
   long, do nothing.)  If this is a symlink (and diskfs_shortcut_symlink
   is set) then this should clear the symlink, even if
   diskfs_create_symlink_hook stores the link target elsewhere.  */
error_t diskfs_truncate (struct node *np, loff_t size);

/* The user must define this function.  Grow the disk allocated to locked node
   NP to be at least SIZE bytes, and set NP->allocsize to the actual
   allocated size.  (If the allocated size is already SIZE bytes, do
   nothing.)  CRED identifies the user responsible for the call.  */
error_t diskfs_grow (struct node *np, loff_t size, struct protid *cred);

/* The user must define this function.  Write to disk (synchronously
   iff WAIT is nonzero) from format-specific buffers any non-paged
   metadata.  If CLEAN is nonzero, then after this is written the
   filesystem will be absolutely clean, and the non-paged metadata can
   so indicate.  */
error_t diskfs_set_hypermetadata (int wait, int clean);

/* The user must define this function.  Allocate a new node to be of
   mode MODE in locked directory DP (don't actually set the mode or
   modify the dir, that will be done by the caller); the user
   responsible for the request can be identified with CRED.  Set *NP
   to be the newly allocated node.  */
error_t diskfs_alloc_node (struct node *dp, mode_t mode, struct node **np);

/* Free node NP; the on disk copy has already been synced with
   diskfs_node_update (where NP->dn_stat.st_mode was 0).  It's
   mode used to be MODE.  */
void diskfs_free_node (struct node *np, mode_t mode);

/* Node NP has no more references; free local state, including *NP
   if it isn't to be retained.  */
void diskfs_node_norefs (struct node *np);

/* The user must define this function unless she wants to use the node
   cache.  See the section `Node cache' below.  Node NP has some light
   references, but has just lost its last hard references.  Take steps
   so that if any light references can be freed, they are.  NP is locked
   as is the pager refcount lock.  This function will be called after
   diskfs_lost_hardrefs.  An additional light reference is acquired by
   libdiskfs across calls to this function.  */
void diskfs_try_dropping_softrefs (struct node *np);

/* The user must define this funcction.  Node NP has some light
   references but has just lost its last hard reference.  NP is locked. */
void diskfs_lost_hardrefs (struct node *np);

/* The user must define this function.  Node NP has just acquired
   a hard reference where it had none previously.  It is thus now
   OK again to have light references without real users.  NP is
   locked. */
void diskfs_new_hardrefs (struct node *np);

/* The user must define this function.  Return non-zero if locked
   directory DP is empty.  If the user does not redefine
   diskfs_clear_directory and diskfs_init_directory, then `empty'
   means `possesses entries labelled . and .. only'.  CRED
   identifies the user making the call (if this user can't search
   the directory, then this routine should fail). */
int diskfs_dirempty (struct node *dp, struct protid *cred);

/* The user may define this function.  Return 0 if NP's mode can be
   changed to MODE; otherwise return an error code.  It must always be
   possible to clear the mode; diskfs will not ask for permission
   before doing so.  */
error_t diskfs_validate_mode_change (struct node *np, mode_t mode);

/* The user may define this function.  Return 0 if NP's owner can be
   changed to UID; otherwise return an error code. */
error_t diskfs_validate_owner_change (struct node *np, uid_t uid);

/* The user may define this function.  Return 0 if NP's group can be
   changed to GID; otherwise return an error code. */
error_t diskfs_validate_group_change (struct node *np, gid_t gid);

/* The user may define this function.  Return 0 if NP's author can be
   changed to AUTHOR; otherwise return an error code. */
error_t diskfs_validate_author_change (struct node *np, uid_t author);

/* The user may define this function.  Return 0 if NP's flags can be
   changed to FLAGS; otherwise return an error code.  It must always
   be possible to clear the flags.   */
error_t diskfs_validate_flags_change (struct node *np, int flags);

/* The user may define this function.  Return 0 if NP's rdev can be
   changed to RDEV; otherwise return an error code. */
error_t diskfs_validate_rdev_change (struct node *np, dev_t rdev);

/* The user must define this function.  Sync the info in NP->dn_stat
   and any associated format-specific information to disk.  If WAIT is true,
   then return only after the physicial media has been completely updated. */
void diskfs_write_disknode (struct node *np, int wait);

/* The user must define this function.  Sync the file contents and all
   associated meta data of file NP to disk (generally this will involve
   calling diskfs_node_update for much of the metadata).  If WAIT is true,
   then return only after the physical media has been completely updated.  */
void diskfs_file_update (struct node *np, int wait);

/* The user must define this function unless she wants to use the node
   cache.  See the section `Node cache' below.  For each active node, call
   FUN.  The node is to be locked around the call to FUN.  If FUN
   returns non-zero for any node, then immediately stop, and return
   that value. */
error_t diskfs_node_iterate (error_t (*fun)(struct node *));

/* The user must define this function.  Sync all the pagers and any
   data belonging on disk except for the hypermetadata.  If WAIT is true,
   then return only after the physicial media has been completely updated. */
void diskfs_sync_everything (int wait);

/* Shutdown all pagers; this is done when the filesystem is exiting and is
   irreversable.  */
void diskfs_shutdown_pager ();

/* The user must define this function.  Return a memory object port (send
   right) for the file contents of NP.  PROT is the maximum allowable
   access.  On errors, return MACH_PORT_NULL and set errno.  */
mach_port_t diskfs_get_filemap (struct node *np, vm_prot_t prot);

/* The user must define this function.  Return true if there are pager
   ports exported that might be in use by users.  If this returns false, then
   further pager creation is also blocked.  */
int diskfs_pager_users ();

/* Return the bitwise or of the maximum prot parameter (the second arg to
   diskfs_get_filemap) for all active user pagers. */
vm_prot_t diskfs_max_user_pager_prot ();

/* The user must define this function.  Return a `struct pager *' suitable
   for use as an argument to diskfs_register_memory_fault_area that
   refers to the pager returned by diskfs_get_filemap for node NP.
   NP is locked.  */
struct pager *diskfs_get_filemap_pager_struct (struct node *np);

/* The user may define this function.  It is called when the disk has been
   changed from read-only to read-write mode or vice-versa.  READONLY is the
   new state (which is also reflected in DISKFS_READONLY).  This function is
   also called during initial startup if the filesystem is to be writable.  */
void diskfs_readonly_changed (int readonly);

/* The user must define this function.  It must invalidate all cached global
   state, and re-read it as necessary from disk, without writing anything.
   It is always called with DISKFS_READONLY true.  diskfs_node_reload is
   subsequently called on all active nodes, so this call needn't re-read any
   node-specific data.  */
error_t diskfs_reload_global_state ();

/* The user must define this function.  It must re-read all data specific to
   NODE from disk, without writing anything.  It is always called with
   DISKFS_READONLY true.  */
error_t diskfs_node_reload (struct node *node);

/* If this function is nonzero (and diskfs_shortcut_symlink is set) it
   is called to set a symlink.  If it returns EINVAL or isn't set,
   then the normal method (writing the contents into the file data) is
   used.  If it returns any other error, it is returned to the user.  */
error_t (*diskfs_create_symlink_hook)(struct node *np, const char *target);

/* If this function is nonzero (and diskfs_shortcut_symlink is set) it
   is called to read the contents of a symlink.  If it returns EINVAL or
   isn't set, then the normal method (reading from the file data) is
   used.  If it returns any other error, it is returned to the user. */
error_t (*diskfs_read_symlink_hook)(struct node *np, char *target);

/* The user may define this function.  The function must set source to
   the source of the translator. The function may return an EOPNOTSUPP
   to indicate that the concept of a source device is not
   applicable. The default function always returns diskfs_disk_name,
   or EOPNOTSUPP if it is NULL. */
error_t diskfs_get_source (char *source, size_t source_len);

/* Libdiskfs contains a node cache.

   Using it relieves the user of implementing diskfs_cached_lookup,
   diskfs_node_iterate, and diskfs_try_dropping_softrefs.

   In order to use it, she must implement the following functions with
   the prefix `diskfs_user_'.  */

/* This can be used to provide additional context to
   diskfs_user_make_node and diskfs_user_read_node in case of cache
   misses.  */
struct lookup_context;

/* The user must define this function if she wants to use the node
   cache.  Create and initialize a node.  */
error_t diskfs_user_make_node (struct node **npp, struct lookup_context *ctx);

/* The user must define this function if she wants to use the node
   cache.  Read stat information out of the on-disk node.  */
error_t diskfs_user_read_node (struct node *np, struct lookup_context *ctx);

/* The user must define this function if she wants to use the node
   cache.  The last hard reference to a node has gone away; arrange to
   have all the weak references dropped that can be.  */
void diskfs_user_try_dropping_softrefs (struct node *np);

/* Lookup node INUM (which must have a reference already) and return it
   without allocating any new references. */
struct node *diskfs_cached_ifind (ino64_t inum);

/* The library exports the following functions for general use */

/* Call this after arguments have been parsed to initialize the library.
   You must call this before calling any other diskfs functions, and after
   parsing diskfs options.  */
error_t diskfs_init_diskfs (void);

/* Call this once the filesystem is fully initialized, to advertise the new
   filesystem control port to our parent filesystem.  If BOOTSTRAP is set,
   the diskfs will call fsys_startup on that port as appropriate and return
   the REALNODE returned in that call; otherwise we return MACH_PORT_NULL.
   FLAGS specifies how to open REALNODE (from the O_* set).  */
mach_port_t diskfs_startup_diskfs (mach_port_t bootstrap, int flags);

/* Call this after all format-specific initialization is done (except
   for setting diskfs_root_node); at this point the pagers should be
   ready to go.  DEMUXER is the demuxer to user.  Normally, this is
   just diskfs_demuxer.  */
void diskfs_spawn_first_thread (ports_demuxer_type demuxer);

/* Once diskfs_root_node is set, call this if we are a bootstrap
   filesystem.  If you call this, then the library will call
   diskfs_init_completed once it has a valid proc and auth port. */
void diskfs_start_bootstrap ();

/* Node NP now has no more references; clean all state.  NP must be
   locked.  */
void diskfs_drop_node (struct node *np);

/* Set on disk fields from NP->dn_stat; update ctime, atime, and mtime
   if necessary.  If WAIT is true, then return only after the physical
   media has been completely updated.  */
void diskfs_node_update (struct node *np, int wait);

/* Add a hard reference to a node.  If there were no hard
   references previously, then the node cannot be locked
   (because you must hold a hard reference to hold the lock). */
void diskfs_nref (struct node *np);

/* Unlock node NP and release a hard reference; if this is the last
   hard reference and there are no links to the file then request
   soft references to be dropped.  */
void diskfs_nput (struct node *np);

/* Release a hard reference on NP.  If NP is locked by anyone, then
   this cannot be the last hard reference (because you must hold a
   hard reference in order to hold the lock).  If this is the last
   hard reference and there are no links, then request soft references
   to be dropped.  */
void diskfs_nrele (struct node *np);

/* Add a light reference to a node. */
void diskfs_nref_light (struct node *np);

/* Unlock node NP and release a light reference */
void diskfs_nput_light (struct node *np);

/* Release a light reference on NP.  If NP is locked by anyone, then
   this cannot be the last reference (because you must hold a
   hard reference in order to hold the lock).  */
void diskfs_nrele_light (struct node *np);

/* Reading and writing of files. this is called by other filesystem
   routines and handles extension of files automatically.  NP is the
   node to be read or written, and must be locked.  DATA will be
   written or filled.  OFF identifies where in thi fel the I/O is to
   take place (-1 is not allowed).  AMT is the size of DATA and tells
   how much to copy.  DIR is 1 for writing and 0 for reading.  CRED is
   the user doing the access (only used to validate attempted file
   extension).  For reads, *AMTREAD is filled with the amount actually
   read.  */
error_t
diskfs_node_rdwr (struct node *np, char *data, loff_t off,
		  size_t amt, int dir, struct protid *cred,
		  size_t *amtread);


/* Send notifications to users who have requested them with
   dir_notice_changes for directory DP.  The type of modification and
   affected name are TYPE and NAME respectively.  This should be
   called by diskfs_direnter, diskfs_dirremove, and diskfs_dirrewrite,
   and anything else that changes the directory, after the change is
   fully completed.  */
void
diskfs_notice_dirchange (struct node *dp, enum dir_changed_type type,
			 const char *name);

/* Send notifications to users who have requested them with
   file_notice_changes for file NP.  The type of modification is TYPE.
   START and END identify the affected region of the file's data.
   This should be called after the change is fully completed.  */
void
diskfs_notice_filechange (struct node *np, enum file_changed_type type,
			  loff_t start, loff_t end);

/* Create a new node structure with DS as its physical disknode.
   The new node will have one hard reference and no light references.  */
struct node *diskfs_make_node (struct disknode *dn);

/* Create a new node structure.  Also allocate SIZE bytes for the
   disknode.  The address of the disknode can be obtained using
   diskfs_node_disknode.  The new node will have one hard reference
   and no light references.  */
struct node *diskfs_make_node_alloc (size_t size);

/* To avoid breaking the ABI whenever sizeof (struct node) changes, we
   explicitly provide the size.  The following two functions will use
   this value for offset calculations.  */
extern const size_t _diskfs_sizeof_struct_node;

/* Return the address of the disknode for NODE.  NODE must have been
   allocated using diskfs_make_node_alloc.  */
struct disknode *diskfs_node_disknode (struct node *node);

/* Return the address of the node for DISKNODE.  DISKNODE must have
   been allocated using diskfs_make_node_alloc.  */
struct node *diskfs_disknode_node (struct disknode *disknode);

#if defined(__USE_EXTERN_INLINES) || defined(DISKFS_DEFINE_EXTERN_INLINE)

/* Return the address of the disknode for NODE.  NODE must have been
   allocated using diskfs_make_node_alloc.  */
DISKFS_EXTERN_INLINE struct disknode *
diskfs_node_disknode (struct node *node)
{
  return (struct disknode *) ((char *) node + _diskfs_sizeof_struct_node);
}

/* Return the address of the node for DISKNODE.  DISKNODE must have
   been allocated using diskfs_make_node_alloc.  */
DISKFS_EXTERN_INLINE struct node *
diskfs_disknode_node (struct disknode *disknode)
{
  return (struct node *) ((char *) disknode - _diskfs_sizeof_struct_node);
}

#endif /* Use extern inlines.  */


/* The library also exports the following functions; they are not generally
   useful unless you are redefining other functions the library provides. */

/* Lookup in directory DP (which is locked) the name NAME.  TYPE will
   either be LOOKUP, CREATE, RENAME, or REMOVE.  CRED identifies the
   user making the call.

   NAME will have leading and trailing slashes stripped.  It is an
   error if there are internal slashes.  NAME will be modified in
   place if there are slashes in it; it is therefore an error to
   specify a constant NAME which contains slashes.

   If the name is found, return zero, and (if NP is nonzero) set *NP
   to point to the node for it, locked.  If the name is not found,
   return ENOENT, and (if NP is nonzero) set *NP to zero.  If NP is
   zero, then the node found must not be locked, even transitorily.
   Lookups for REMOVE and RENAME (which must often check permissions
   on the node being found) will always set NP.

   If DS is nonzero then:
     For LOOKUP: set *DS to be ignored by diskfs_drop_dirstat.
     For CREATE: on success, set *DS to be ignored by diskfs_drop_dirstat.
                 on failure, set *DS for a future call to diskfs_direnter.
     For RENAME: on success, set *DS for a future call to diskfs_dirrewrite.
                 on failure, set *DS for a future call to diskfs_direnter.
     For REMOVE: on success, set *DS for a future call to diskfs_dirremove.
                 on failure, set *DS to be ignored by diskfs_drop_dirstat.
   The caller of this function guarantees that if DS is nonzero, then
   either the appropriate call listed above or diskfs_drop_dirstat will
   be called with DS before the directory DP is unlocked, and guarantees
   that no lookup calls will be made on this directory between this
   lookup and the use (or descruction) of *DS.

   If you use the library's versions of diskfs_rename_dir,
   diskfs_clear_directory, and diskfs_init_dir, then lookups for `..'
   might have the flag SPEC_DOTDOT or'd in.  This has the following special
   meaning:
   For LOOKUP: DP should be unlocked and its reference dropped before
               returning.
   For RENAME and REMOVE: The node being found (*NP) is already held
               locked, so don't lock it or add a reference to it.
   (SPEC_DOTDOT will not be given with CREATE.)

   Return ENOTDIR if DP is not a directory.
   Return EACCES if CRED isn't allowed to search DP.
   Return EACCES if completing the operation will require writing
   the directory and diskfs_checkdirmod won't allow the modification.
   Return ENOENT if NAME isn't in the directory.
   Return EAGAIN if NAME refers to the `..' of this filesystem's root.
   Return EIO if appropriate.

   This function is a wrapper for diskfs_lookup_hard.
*/
error_t diskfs_lookup (struct node *dp,
		       const char *name, enum lookup_type type,
		       struct node **np, struct dirstat *ds,
		       struct protid *cred);

/* Add NP to directory DP under the name NAME.  This will only be
   called after an unsuccessful call to diskfs_lookup of type CREATE
   or RENAME; DP has been locked continuously since that call and DS
   is as that call set it, NP is locked.  CRED identifies the user
   responsible for the call (to be used only to validate directory
   growth).  This function is a wrapper for diskfs_direnter_hard.  */
error_t
diskfs_direnter (struct node *dp, const char *name, struct node *np,
		 struct dirstat *ds, struct protid *cred);

/* This will only be called after a successful call to diskfs_lookup
   of type RENAME; this call should change the name found in directory
   DP to point to node NP instead of its previous referent, OLDNP.  DP
   has been locked continuously since the call to diskfs_lookup and DS
   is as that call set it; NP is locked.  This routine should call
   diskfs_notice_dirchange if DP->dirmod_reqs is nonzero.  NAME is the
   name of OLDNP inside DP; it is this reference which is being
   rewritten. This function is a wrapper for diskfs_dirrewrite_hard.  */
error_t diskfs_dirrewrite (struct node *dp, struct node *oldnp,
			   struct node *np, const char *name,
			   struct dirstat *ds);

/* This will only be called after a successful call to diskfs_lookup
   of type REMOVE; this call should remove the name found from the
   directory DS.  DP has been locked continuously since the call to
   diskfs_lookup and DS is as that call set it.  This routine should
   call diskfs_notice_dirchange if DP->dirmod_reqs is nonzero.  This
   function is a wrapper for diskfs_dirremove_hard.  The entry being
   removed has name NAME and refers to NP.  */
error_t diskfs_dirremove (struct node *dp, struct node *np,
			  const char *name, struct dirstat *ds);

/* The user must define this function unless she wants to use the node
   cache.  See the section `Node cache' above.  Return the node
   corresponding to CACHE_ID in *NPP. */
error_t diskfs_cached_lookup (ino64_t cache_id, struct node **npp);

/* Return the node corresponding to CACHE_ID in *NPP.  In case of a
   cache miss, use CTX to create it and load it from the disk.  See
   the section `Node cache' above.  */
error_t diskfs_cached_lookup_context (ino64_t inum, struct node **npp,
				      struct lookup_context *ctx);


/* Create a new node. Give it MODE; if that includes IFDIR, also
   initialize `.' and `..' in the new directory.  Return the node in NPP.
   CRED identifies the user responsible for the call.  If NAME is nonzero,
   then link the new node into DIR with name NAME; DS is the result of a
   prior diskfs_lookup for creation (and DIR has been held locked since).
   DIR must always be provided as at least a hint for disk allocation
   strategies.  */
error_t
diskfs_create_node (struct node *dir, const char *name, mode_t mode,
		    struct node **newnode, struct protid *cred,
		    struct dirstat *ds);

/* Create and return a protid for an existing peropen PO in CRED,
   referring to user USER.  On success, consume a reference to PO.  */
error_t diskfs_create_protid (struct peropen *po, struct iouser *user,
			      struct protid **cred);

/* Build and return in CRED a protid which has no user identification, for
   peropen PO.  On success, consume a reference to PO.  */
error_t diskfs_start_protid (struct peropen *po, struct protid **cred);

/* Finish building protid CRED started with diskfs_start_protid;
   the user to install is USER.  */
void diskfs_finish_protid (struct protid *cred, struct iouser *user);

extern struct protid * diskfs_begin_using_protid_port (file_t port);
extern struct protid *
diskfs_begin_using_protid_payload (unsigned long payload);
extern struct diskfs_control * diskfs_begin_using_control_port (fsys_t port);
extern struct diskfs_control *
diskfs_begin_using_control_port_payload (unsigned long payload);
extern struct bootinfo *diskfs_begin_using_bootinfo_port (exec_startup_t port);
struct bootinfo *
diskfs_begin_using_bootinfo_payload (unsigned long payload);

extern void diskfs_end_using_protid_port (struct protid *cred);
extern void diskfs_end_using_control_port (struct diskfs_control *cred);
extern void diskfs_end_using_bootinfo (struct bootinfo *upt);

#if defined(__USE_EXTERN_INLINES) || defined(DISKFS_DEFINE_EXTERN_INLINE)

/* Called by MiG to translate ports into struct protid *.
   fsmutations.h arranges for this to happen for the io and
   fs interfaces. */
DISKFS_EXTERN_INLINE struct protid *
diskfs_begin_using_protid_port (file_t port)
{
  return ports_lookup_port (diskfs_port_bucket, port, diskfs_protid_class);
}

DISKFS_EXTERN_INLINE struct protid *
diskfs_begin_using_protid_payload (unsigned long payload)
{
  return ports_lookup_payload (diskfs_port_bucket,
			       payload,
			       diskfs_protid_class);
}

/* And for the fsys interface. */
DISKFS_EXTERN_INLINE struct diskfs_control *
diskfs_begin_using_control_port (fsys_t port)
{
  return ports_lookup_port (diskfs_port_bucket, port, diskfs_control_class);
}

DISKFS_EXTERN_INLINE struct diskfs_control *
diskfs_begin_using_control_port_payload (unsigned long payload)
{
  return ports_lookup_payload (diskfs_port_bucket,
			       payload,
			       diskfs_control_class);
}

/* And for the exec_startup interface. */
DISKFS_EXTERN_INLINE struct bootinfo *
diskfs_begin_using_bootinfo_port (exec_startup_t port)
{
  return ports_lookup_port (diskfs_port_bucket, port, diskfs_execboot_class);
}

DISKFS_EXTERN_INLINE struct bootinfo *
diskfs_begin_using_bootinfo_payload (unsigned long payload)
{
  return ports_lookup_payload (diskfs_port_bucket,
			       payload,
			       diskfs_execboot_class);
}

/* Called by MiG after server routines have been run; this
   balances begin_using_protid_port, and is arranged for the io
   and fs interfaces by fsmutations.h. */
DISKFS_EXTERN_INLINE void
diskfs_end_using_protid_port (struct protid *cred)
{
  if (cred)
    ports_port_deref (cred);
}

/* And for the fsys interface. */
DISKFS_EXTERN_INLINE void
diskfs_end_using_control_port (struct diskfs_control *cred)
{
  if (cred)
    ports_port_deref (cred);
}

/* And for the exec_startup interface. */
DISKFS_EXTERN_INLINE void
diskfs_end_using_bootinfo (struct bootinfo *b)
{
  if (b)
    ports_port_deref (b);
}

#endif /* Use extern inlines.  */

/* Called when a protid CRED has no more references.  (Because references\
   to protids are maintained by the port management library, this is
   installed in the clean routines list.)  The ports library will
   free the structure for us.  */
void diskfs_protid_rele (void *arg);

/* Create a new peropen structure on node NP with open flags FLAGS in
   *PPO.  The initial values for the root_parent, shadow_root, and
   shadow_root_parent fields are copied from CONTEXT if it's non-zero,
   otherwise they are zeroed.  */
error_t
diskfs_make_peropen (struct node *np, int flags,
		     struct peropen *context, struct peropen **ppo);

/* Decrement the reference count on a peropen structure. */
void diskfs_release_peropen (struct peropen *po);

/* Node NP has just been found in DIR with NAME.  If NP is null, that
   means that this name has been confirmed as absent in the directory. */
void diskfs_enter_lookup_cache (struct node *dir, struct node *np,
				const char *name);

/* Purge all references in the cache to NP as a node inside
   directory DP. */
void diskfs_purge_lookup_cache (struct node *dp, struct node *np);

/* Scan the cache looking for NAME inside DIR.  If we don't know
   anything entry at all, then return 0.  If the entry is confirmed to
   not exist, then return -1.  Otherwise, return NP for the entry, with
   a newly allocated reference. */
struct node *diskfs_check_lookup_cache (struct node *dir, const char *name);

/* Rename directory node FNP (whose parent is FDP, and which has name
   FROMNAME in that directory) to have name TONAME inside directory
   TDP.  None of these nodes are locked, and none should be locked
   upon return.  This routine is serialized, so it doesn't have to be
   reentrant.  Directories will never be renamed except by this
   routine.  FROMCRED and TOCRED are the users responsible for
   FDP/FNP and TDP respectively. If EXCL is set, then fail if TONAME
   already exists inside directory TDP. This routine assumes the usual
   convention where `.' and `..' are represented by ordinary links;
   if that is not true for your format, you have to redefine this
   function.*/
error_t
diskfs_rename_dir (struct node *fdp, struct node *fnp, const char *fromname,
		   struct node *tdp, const char *toname,
		   struct protid *fromcred, struct protid *tocred, int excl);

/* Clear the `.' and `..' entries from directory DP.  Its parent is
   PDP, and the user responsible for this is identified by CRED.  Both
   directories must be locked.  This routine assumes the usual
   convention where `.' and `..' are represented by ordinary links; if
   that is not true for your format, you have to redefine this
   function. */
error_t diskfs_clear_directory (struct node *dp, struct node *pdp,
				struct protid *cred);

/* Locked node DP is a new directory; add whatever links are necessary
   to give it structure; its parent is the (locked) node PDP.
   This routine may not call diskfs_lookup on PDP.  The new directory
   must be clear within the meaning of diskfs_dirempty.  This routine
   assumes the usual convention where `.' and `..' are represented by
   ordinary links; if that is not true for your format, you have to
   redefine this function.   CRED identifies the user making the call. */
error_t
diskfs_init_dir (struct node *dp, struct node *pdp, struct protid *cred);

/* If disk is not readonly and the noatime option is not enabled, set
   NP->dn_set_atime.  */
void diskfs_set_node_atime (struct node *np);

/* If NP->dn_set_ctime is set, then modify NP->dn_stat.st_ctim
   appropriately; do the analogous operation for atime and mtime as well. */
void diskfs_set_node_times (struct node *np);

/* Shutdown the filesystem; flags are as for fsys_goaway. */
error_t diskfs_shutdown (int flags);

/* Change an active filesystem between read-only and writable modes, setting
   the global variable DISKFS_READONLY to reflect the current mode.  If an
   error is returned, nothing will have changed.  DISKFS_FSYS_LOCK should be
   held while calling this routine.  */
error_t diskfs_set_readonly (int readonly);

/* Re-read all incore data structures from disk.  This will only work if
   DISKFS_READONLY is true.  DISKFS_FSYS_LOCK should be held while calling
   this routine.  */
error_t diskfs_remount ();

/* Called by S_fsys_startup for execserver bootstrap.  The execserver
   is able to function without a real node, hence this fraud.  Arguments
   are all as for fsys_startup in <hurd/fsys.defs>.  */
error_t diskfs_execboot_fsys_startup (mach_port_t port, int flags,
				      mach_port_t ctl, mach_port_t *real,
				      mach_msg_type_name_t *realpoly);

/* Establish a thread to sync the filesystem every INTERVAL seconds, or
   never, if INTERVAL is zero.  If an error occurs creating the thread, it is
   returned, otherwise 0.  Subsequent calls will create a new thread and
   (eventually) get rid of the old one; the old thread won't do any more
   syncs, regardless.  */
error_t diskfs_set_sync_interval (int interval);

/* Parse and execute the runtime options in ARGZ & ARGZ_LEN.  EINVAL is
   returned if some option is unrecognized.  The default definition of this
   routine will parse them using DISKFS_RUNTIME_ARGP, which see.  */
error_t diskfs_set_options (const char *argz, size_t argz_len);

/* Append to the malloced string *ARGZ of length *ARGZ_LEN a NUL-separated
   list of the arguments to this translator.  The default definition of this
   routine simply calls diskfs_append_std_options.  */
error_t diskfs_append_args (char **argz, size_t *argz_len);

/* If this is defined or set to an argp structure, it will be used by the
   default diskfs_set_options to handle runtime option parsing.  The default
   definition is initialized to a pointer to DISKFS_STD_RUNTIME_ARGP.  */
extern struct argp *diskfs_runtime_argp;

/* An argp for the standard diskfs runtime options.  The default definition
   of DISKFS_RUNTIME_ARGP points to this, although if the user redefines
   that, he may chain this onto his argp as well.  */
extern const struct argp diskfs_std_runtime_argp;

/* An argp structure for the standard diskfs command line arguments.  The
   user may call argp_parse on this to parse the command line, chain it onto
   the end of his own argp structure, or ignore it completely.  */
extern const struct argp diskfs_startup_argp;

/* An argp structure for the standard diskfs command line arguments plus a
   store specification.  The address of a location in which to return the
   resulting struct store_parsed structure should be passed as the input
   argument to argp_parse; see the declaration for STORE_ARGP in
   <hurd/store.h> for more information.  */
extern const struct argp diskfs_store_startup_argp;

/* *Appends* to ARGZ & ARGZ_LEN '\0'-separated options describing the standard
   diskfs option state (note that unlike diskfs_get_options, ARGZ & ARGZ_LEN
   must already have a sane value).  */
error_t diskfs_append_std_options (char **argz, size_t *argz_len);

/* Demultiplex incoming messages on ports created by libdiskfs.  */
int diskfs_demuxer (mach_msg_header_t *, mach_msg_header_t *);

/* Check if the filesystem is readonly before an operation that
   writes it.  Return 1 if readonly, zero otherwise. */
int diskfs_check_readonly (void);

/* The diskfs library provides functions to demultiplex the fs, io,
   fsys, interrupt, and notify interfaces.  All the server routines
   have the prefix `diskfs_S_'; `in' arguments of type file_t or io_t
   appear as `struct protid *' to the stub.  */


/* All-in-one initialization function for diskfs filesystems using
   libstore.  This parses arguments using STARTUP_ARGP (defaulting to
   diskfs_store_startup_argp if it's null; note that the ARGP_IN_ORDER
   flag is always used); it calls diskfs_init_diskfs; it opens the
   store with store_parsed_open, and sets diskfs_hard_readonly and
   diskfs_readonly if the store is unwritable; it calls
   diskfs_spawn_first_thread; finally, it returns the store and its
   description in *STORE and *STORE_PARSED, and the bootstrap port in
   *BOOTSTRAP.  The caller should pass *BOOTSTRAP to
   diskfs_startup_diskfs after setting diskfs_root_node.
   (See <argp.h> and <hurd/store.h>.)

   This call cannot return failure; if it encounters a fatal problem,
   it prints a diagnostic on stderr (or the console) and exits the
   program.  */
struct store *diskfs_init_main (struct argp *startup_argp,
				int argc, char **argv,
				struct store_parsed **store_parsed,
				mach_port_t *bootstrap);

/* The following are optional convenience routines and global variable, which
   can be used by any user program that uses a mach device to hold the
   underlying filesystem.  */

/* Make errors go somewhere reasonable.  */
void diskfs_console_stdio ();

#endif	/* hurd/diskfs.h */