include/linux/lm_interface.h - linux/kernel/git/bpf/bpf-next - Git at Google

 /*
  * Copyright (C) Sistina Software, Inc.  1997-2003 All rights reserved.
  * Copyright (C) 2004-2006 Red Hat, Inc.  All rights reserved.
  *
  * This copyrighted material is made available to anyone wishing to use,
  * modify, copy, or redistribute it subject to the terms and conditions
  * of the GNU General Public License version 2.
  */

 #ifndef __LM_INTERFACE_DOT_H__
 #define __LM_INTERFACE_DOT_H__


 typedef void (*lm_callback_t) (void *ptr, unsigned int type, void *data);

 /*
  * lm_mount() flags
  *
  * LM_MFLAG_SPECTATOR
  * GFS is asking to join the filesystem's lockspace, but it doesn't want to
  * modify the filesystem.  The lock module shouldn't assign a journal to the FS
  * mount.  It shouldn't send recovery callbacks to the FS mount.  If the node
  * dies or withdraws, all locks can be wiped immediately.
  */

 #define LM_MFLAG_SPECTATOR	0x00000001

 /*
  * lm_lockstruct flags
  *
  * LM_LSFLAG_LOCAL
  * The lock_nolock module returns LM_LSFLAG_LOCAL to GFS, indicating that GFS
  * can make single-node optimizations.
  */

 #define LM_LSFLAG_LOCAL		0x00000001

 /*
  * lm_lockname types
  */

 #define LM_TYPE_RESERVED	0x00
 #define LM_TYPE_NONDISK		0x01
 #define LM_TYPE_INODE		0x02
 #define LM_TYPE_RGRP		0x03
 #define LM_TYPE_META		0x04
 #define LM_TYPE_IOPEN		0x05
 #define LM_TYPE_FLOCK		0x06
 #define LM_TYPE_PLOCK		0x07
 #define LM_TYPE_QUOTA		0x08
 #define LM_TYPE_JOURNAL		0x09

 /*
  * lm_lock() states
  *
  * SHARED is compatible with SHARED, not with DEFERRED or EX.
  * DEFERRED is compatible with DEFERRED, not with SHARED or EX.
  */

 #define LM_ST_UNLOCKED		0
 #define LM_ST_EXCLUSIVE		1
 #define LM_ST_DEFERRED		2
 #define LM_ST_SHARED		3

 /*
  * lm_lock() flags
  *
  * LM_FLAG_TRY
  * Don't wait to acquire the lock if it can't be granted immediately.
  *
  * LM_FLAG_TRY_1CB
  * Send one blocking callback if TRY is set and the lock is not granted.
  *
  * LM_FLAG_NOEXP
  * GFS sets this flag on lock requests it makes while doing journal recovery.
  * These special requests should not be blocked due to the recovery like
  * ordinary locks would be.
  *
  * LM_FLAG_ANY
  * A SHARED request may also be granted in DEFERRED, or a DEFERRED request may
  * also be granted in SHARED.  The preferred state is whichever is compatible
  * with other granted locks, or the specified state if no other locks exist.
  *
  * LM_FLAG_PRIORITY
  * Override fairness considerations.  Suppose a lock is held in a shared state
  * and there is a pending request for the deferred state.  A shared lock
  * request with the priority flag would be allowed to bypass the deferred
  * request and directly join the other shared lock.  A shared lock request
  * without the priority flag might be forced to wait until the deferred
  * requested had acquired and released the lock.
  */

 #define LM_FLAG_TRY		0x00000001
 #define LM_FLAG_TRY_1CB		0x00000002
 #define LM_FLAG_NOEXP		0x00000004
 #define LM_FLAG_ANY		0x00000008
 #define LM_FLAG_PRIORITY	0x00000010

 /*
  * lm_lock() and lm_async_cb return flags
  *
  * LM_OUT_ST_MASK
  * Masks the lower two bits of lock state in the returned value.
  *
  * LM_OUT_CACHEABLE
  * The lock hasn't been released so GFS can continue to cache data for it.
  *
  * LM_OUT_CANCELED
  * The lock request was canceled.
  *
  * LM_OUT_ASYNC
  * The result of the request will be returned in an LM_CB_ASYNC callback.
  */

 #define LM_OUT_ST_MASK		0x00000003
 #define LM_OUT_CACHEABLE	0x00000004
 #define LM_OUT_CANCELED		0x00000008
 #define LM_OUT_ASYNC		0x00000080
 #define LM_OUT_ERROR		0x00000100

 /*
  * lm_callback_t types
  *
  * LM_CB_NEED_E LM_CB_NEED_D LM_CB_NEED_S
  * Blocking callback, a remote node is requesting the given lock in
  * EXCLUSIVE, DEFERRED, or SHARED.
  *
  * LM_CB_NEED_RECOVERY
  * The given journal needs to be recovered.
  *
  * LM_CB_DROPLOCKS
  * Reduce the number of cached locks.
  *
  * LM_CB_ASYNC
  * The given lock has been granted.
  */

 #define LM_CB_NEED_E		257
 #define LM_CB_NEED_D		258
 #define LM_CB_NEED_S		259
 #define LM_CB_NEED_RECOVERY	260
 #define LM_CB_DROPLOCKS		261
 #define LM_CB_ASYNC		262

 /*
  * lm_recovery_done() messages
  */

 #define LM_RD_GAVEUP		308
 #define LM_RD_SUCCESS		309


 struct lm_lockname {
 	u64 ln_number;
 	unsigned int ln_type;
 };

 #define lm_name_equal(name1, name2) \
 	(((name1)->ln_number == (name2)->ln_number) && \
 	 ((name1)->ln_type == (name2)->ln_type)) \

 struct lm_async_cb {
 	struct lm_lockname lc_name;
 	int lc_ret;
 };

 struct lm_lockstruct;

 struct lm_lockops {
 	const char *lm_proto_name;

 	/*
 	 * Mount/Unmount
 	 */

 	int (*lm_mount) (char *table_name, char *host_data,
 			 lm_callback_t cb, void *cb_data,
 			 unsigned int min_lvb_size, int flags,
 			 struct lm_lockstruct *lockstruct,
 			 struct kobject *fskobj);

 	void (*lm_others_may_mount) (void *lockspace);

 	void (*lm_unmount) (void *lockspace);

 	void (*lm_withdraw) (void *lockspace);

 	/*
 	 * Lock oriented operations
 	 */

 	int (*lm_get_lock) (void *lockspace, struct lm_lockname *name, void **lockp);

 	void (*lm_put_lock) (void *lock);

 	unsigned int (*lm_lock) (void *lock, unsigned int cur_state,
 				 unsigned int req_state, unsigned int flags);

 	unsigned int (*lm_unlock) (void *lock, unsigned int cur_state);

 	void (*lm_cancel) (void *lock);

 	int (*lm_hold_lvb) (void *lock, char **lvbp);
 	void (*lm_unhold_lvb) (void *lock, char *lvb);

 	/*
 	 * Posix Lock oriented operations
 	 */

 	int (*lm_plock_get) (void *lockspace, struct lm_lockname *name,
 			     struct file *file, struct file_lock *fl);

 	int (*lm_plock) (void *lockspace, struct lm_lockname *name,
 			 struct file *file, int cmd, struct file_lock *fl);

 	int (*lm_punlock) (void *lockspace, struct lm_lockname *name,
 			   struct file *file, struct file_lock *fl);

 	/*
 	 * Client oriented operations
 	 */

 	void (*lm_recovery_done) (void *lockspace, unsigned int jid,
 				  unsigned int message);

 	struct module *lm_owner;
 };

 /*
  * lm_mount() return values
  *
  * ls_jid - the journal ID this node should use
  * ls_first - this node is the first to mount the file system
  * ls_lvb_size - size in bytes of lock value blocks
  * ls_lockspace - lock module's context for this file system
  * ls_ops - lock module's functions
  * ls_flags - lock module features
  */

 struct lm_lockstruct {
 	unsigned int ls_jid;
 	unsigned int ls_first;
 	unsigned int ls_lvb_size;
 	void *ls_lockspace;
 	const struct lm_lockops *ls_ops;
 	int ls_flags;
 };

 /*
  * Lock module bottom interface.  A lock module makes itself available to GFS
  * with these functions.
  */

 int gfs2_register_lockproto(const struct lm_lockops *proto);
 void gfs2_unregister_lockproto(const struct lm_lockops *proto);

 /*
  * Lock module top interface.  GFS calls these functions when mounting or
  * unmounting a file system.
  */

 int gfs2_mount_lockproto(char *proto_name, char *table_name, char *host_data,
 			 lm_callback_t cb, void *cb_data,
 			 unsigned int min_lvb_size, int flags,
 			 struct lm_lockstruct *lockstruct,
 			 struct kobject *fskobj);

 void gfs2_unmount_lockproto(struct lm_lockstruct *lockstruct);

 void gfs2_withdraw_lockproto(struct lm_lockstruct *lockstruct);

 #endif /* __LM_INTERFACE_DOT_H__ */
	/*
	* Copyright (C) Sistina Software, Inc. 1997-2003 All rights reserved.
	* Copyright (C) 2004-2006 Red Hat, Inc. All rights reserved.
	*
	* This copyrighted material is made available to anyone wishing to use,
	* modify, copy, or redistribute it subject to the terms and conditions
	* of the GNU General Public License version 2.
	*/

	#ifndef __LM_INTERFACE_DOT_H__
	#define __LM_INTERFACE_DOT_H__


	typedef void (lm_callback_t) (void ptr, unsigned int type, void *data);

	/*
	* lm_mount() flags
	*
	* LM_MFLAG_SPECTATOR
	* GFS is asking to join the filesystem's lockspace, but it doesn't want to
	* modify the filesystem. The lock module shouldn't assign a journal to the FS
	* mount. It shouldn't send recovery callbacks to the FS mount. If the node
	* dies or withdraws, all locks can be wiped immediately.
	*/

	#define LM_MFLAG_SPECTATOR 0x00000001

	/*
	* lm_lockstruct flags
	*
	* LM_LSFLAG_LOCAL
	* The lock_nolock module returns LM_LSFLAG_LOCAL to GFS, indicating that GFS
	* can make single-node optimizations.
	*/

	#define LM_LSFLAG_LOCAL 0x00000001

	/*
	* lm_lockname types
	*/

	#define LM_TYPE_RESERVED 0x00
	#define LM_TYPE_NONDISK 0x01
	#define LM_TYPE_INODE 0x02
	#define LM_TYPE_RGRP 0x03
	#define LM_TYPE_META 0x04
	#define LM_TYPE_IOPEN 0x05
	#define LM_TYPE_FLOCK 0x06
	#define LM_TYPE_PLOCK 0x07
	#define LM_TYPE_QUOTA 0x08
	#define LM_TYPE_JOURNAL 0x09

	/*
	* lm_lock() states
	*
	* SHARED is compatible with SHARED, not with DEFERRED or EX.
	* DEFERRED is compatible with DEFERRED, not with SHARED or EX.
	*/

	#define LM_ST_UNLOCKED 0
	#define LM_ST_EXCLUSIVE 1
	#define LM_ST_DEFERRED 2
	#define LM_ST_SHARED 3

	/*
	* lm_lock() flags
	*
	* LM_FLAG_TRY
	* Don't wait to acquire the lock if it can't be granted immediately.
	*
	* LM_FLAG_TRY_1CB
	* Send one blocking callback if TRY is set and the lock is not granted.
	*
	* LM_FLAG_NOEXP
	* GFS sets this flag on lock requests it makes while doing journal recovery.
	* These special requests should not be blocked due to the recovery like
	* ordinary locks would be.
	*
	* LM_FLAG_ANY
	* A SHARED request may also be granted in DEFERRED, or a DEFERRED request may
	* also be granted in SHARED. The preferred state is whichever is compatible
	* with other granted locks, or the specified state if no other locks exist.
	*
	* LM_FLAG_PRIORITY
	* Override fairness considerations. Suppose a lock is held in a shared state
	* and there is a pending request for the deferred state. A shared lock
	* request with the priority flag would be allowed to bypass the deferred
	* request and directly join the other shared lock. A shared lock request
	* without the priority flag might be forced to wait until the deferred
	* requested had acquired and released the lock.
	*/

	#define LM_FLAG_TRY 0x00000001
	#define LM_FLAG_TRY_1CB 0x00000002
	#define LM_FLAG_NOEXP 0x00000004
	#define LM_FLAG_ANY 0x00000008
	#define LM_FLAG_PRIORITY 0x00000010

	/*
	* lm_lock() and lm_async_cb return flags
	*
	* LM_OUT_ST_MASK
	* Masks the lower two bits of lock state in the returned value.
	*
	* LM_OUT_CACHEABLE
	* The lock hasn't been released so GFS can continue to cache data for it.
	*
	* LM_OUT_CANCELED
	* The lock request was canceled.
	*
	* LM_OUT_ASYNC
	* The result of the request will be returned in an LM_CB_ASYNC callback.
	*/

	#define LM_OUT_ST_MASK 0x00000003
	#define LM_OUT_CACHEABLE 0x00000004
	#define LM_OUT_CANCELED 0x00000008
	#define LM_OUT_ASYNC 0x00000080
	#define LM_OUT_ERROR 0x00000100

	/*
	* lm_callback_t types
	*
	* LM_CB_NEED_E LM_CB_NEED_D LM_CB_NEED_S
	* Blocking callback, a remote node is requesting the given lock in
	* EXCLUSIVE, DEFERRED, or SHARED.
	*
	* LM_CB_NEED_RECOVERY
	* The given journal needs to be recovered.
	*
	* LM_CB_DROPLOCKS
	* Reduce the number of cached locks.
	*
	* LM_CB_ASYNC
	* The given lock has been granted.
	*/

	#define LM_CB_NEED_E 257
	#define LM_CB_NEED_D 258
	#define LM_CB_NEED_S 259
	#define LM_CB_NEED_RECOVERY 260
	#define LM_CB_DROPLOCKS 261
	#define LM_CB_ASYNC 262

	/*
	* lm_recovery_done() messages
	*/

	#define LM_RD_GAVEUP 308
	#define LM_RD_SUCCESS 309


	struct lm_lockname {
	u64 ln_number;
	unsigned int ln_type;
	};

	#define lm_name_equal(name1, name2) \
	(((name1)->ln_number == (name2)->ln_number) && \
	((name1)->ln_type == (name2)->ln_type)) \

	struct lm_async_cb {
	struct lm_lockname lc_name;
	int lc_ret;
	};

	struct lm_lockstruct;

	struct lm_lockops {
	const char *lm_proto_name;

	/*
	* Mount/Unmount
	*/

	int (lm_mount) (char table_name, char *host_data,
	lm_callback_t cb, void *cb_data,
	unsigned int min_lvb_size, int flags,
	struct lm_lockstruct *lockstruct,
	struct kobject *fskobj);

	void (lm_others_may_mount) (void lockspace);

	void (lm_unmount) (void lockspace);

	void (lm_withdraw) (void lockspace);

	/*
	* Lock oriented operations
	*/

	int (lm_get_lock) (void lockspace, struct lm_lockname name, void *lockp);

	void (lm_put_lock) (void lock);

	unsigned int (lm_lock) (void lock, unsigned int cur_state,
	unsigned int req_state, unsigned int flags);

	unsigned int (lm_unlock) (void lock, unsigned int cur_state);

	void (lm_cancel) (void lock);

	int (lm_hold_lvb) (void lock, char **lvbp);
	void (lm_unhold_lvb) (void lock, char *lvb);

	/*
	* Posix Lock oriented operations
	*/

	int (lm_plock_get) (void lockspace, struct lm_lockname *name,
	struct file file, struct file_lock fl);

	int (lm_plock) (void lockspace, struct lm_lockname *name,
	struct file file, int cmd, struct file_lock fl);

	int (lm_punlock) (void lockspace, struct lm_lockname *name,
	struct file file, struct file_lock fl);

	/*
	* Client oriented operations
	*/

	void (lm_recovery_done) (void lockspace, unsigned int jid,
	unsigned int message);

	struct module *lm_owner;
	};

	/*
	* lm_mount() return values
	*
	* ls_jid - the journal ID this node should use
	* ls_first - this node is the first to mount the file system
	* ls_lvb_size - size in bytes of lock value blocks
	* ls_lockspace - lock module's context for this file system
	* ls_ops - lock module's functions
	* ls_flags - lock module features
	*/

	struct lm_lockstruct {
	unsigned int ls_jid;
	unsigned int ls_first;
	unsigned int ls_lvb_size;
	void *ls_lockspace;
	const struct lm_lockops *ls_ops;
	int ls_flags;
	};

	/*
	* Lock module bottom interface. A lock module makes itself available to GFS
	* with these functions.
	*/

	int gfs2_register_lockproto(const struct lm_lockops *proto);
	void gfs2_unregister_lockproto(const struct lm_lockops *proto);

	/*
	* Lock module top interface. GFS calls these functions when mounting or
	* unmounting a file system.
	*/

	int gfs2_mount_lockproto(char proto_name, char table_name, char *host_data,
	lm_callback_t cb, void *cb_data,
	unsigned int min_lvb_size, int flags,
	struct lm_lockstruct *lockstruct,
	struct kobject *fskobj);

	void gfs2_unmount_lockproto(struct lm_lockstruct *lockstruct);

	void gfs2_withdraw_lockproto(struct lm_lockstruct *lockstruct);

	#endif /* __LM_INTERFACE_DOT_H__ */