drivers/staging/lustre/lustre/include/lustre_disk.h - pub/scm/linux/kernel/git/arnd/playground - Git at Google

 /*
  * GPL HEADER START
  *
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 only,
  * as published by the Free Software Foundation.
  *
  * 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 version 2 for more details (a copy is included
  * in the LICENSE file that accompanied this code).
  *
  * You should have received a copy of the GNU General Public License
  * version 2 along with this program; If not, see
  * http://www.sun.com/software/products/lustre/docs/GPLv2.pdf
  *
  * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
  * CA 95054 USA or visit www.sun.com if you need additional information or
  * have any questions.
  *
  * GPL HEADER END
  */
 /*
  * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved.
  * Use is subject to license terms.
  *
  * Copyright (c) 2011, 2012, Intel Corporation.
  */
 /*
  * This file is part of Lustre, http://www.lustre.org/
  * Lustre is a trademark of Sun Microsystems, Inc.
  *
  * lustre/include/lustre_disk.h
  *
  * Lustre disk format definitions.
  *
  * Author: Nathan Rutman <nathan@clusterfs.com>
  */

 #ifndef _LUSTRE_DISK_H
 #define _LUSTRE_DISK_H

 /** \defgroup disk disk
  *
  * @{
  */

 #include "../../include/linux/libcfs/libcfs.h"
 #include "../../include/linux/lnet/types.h"
 #include <linux/backing-dev.h>

 /****************** persistent mount data *********************/

 #define LDD_F_SV_TYPE_MDT   0x0001
 #define LDD_F_SV_TYPE_OST   0x0002
 #define LDD_F_SV_TYPE_MGS   0x0004
 #define LDD_F_SV_TYPE_MASK (LDD_F_SV_TYPE_MDT  | \
 			    LDD_F_SV_TYPE_OST  | \
 			    LDD_F_SV_TYPE_MGS)
 #define LDD_F_SV_ALL	0x0008

 /****************** mount command *********************/

 /* The lmd is only used internally by Lustre; mount simply passes
    everything as string options */

 #define LMD_MAGIC    0xbdacbd03

 /* gleaned from the mount command - no persistent info here */
 struct lustre_mount_data {
 	__u32      lmd_magic;
 	__u32      lmd_flags;	 /* lustre mount flags */
 	int	lmd_mgs_failnodes; /* mgs failover node count */
 	int	lmd_exclude_count;
 	int	lmd_recovery_time_soft;
 	int	lmd_recovery_time_hard;
 	char      *lmd_dev;	   /* device name */
 	char      *lmd_profile;       /* client only */
 	char      *lmd_mgssec;	/* sptlrpc flavor to mgs */
 	char      *lmd_opts;	  /* lustre mount options (as opposed to
 					 _device_ mount options) */
 	char      *lmd_params;	/* lustre params */
 	__u32     *lmd_exclude;       /* array of OSTs to ignore */
 	char	*lmd_mgs;	   /* MGS nid */
 	char	*lmd_osd_type;      /* OSD type */
 };

 #define LMD_FLG_SERVER		0x0001	/* Mounting a server */
 #define LMD_FLG_CLIENT		0x0002	/* Mounting a client */
 #define LMD_FLG_ABORT_RECOV	0x0008	/* Abort recovery */
 #define LMD_FLG_NOSVC		0x0010	/* Only start MGS/MGC for servers,
 					   no other services */
 #define LMD_FLG_NOMGS		0x0020	/* Only start target for servers, reusing
 					   existing MGS services */
 #define LMD_FLG_WRITECONF	0x0040	/* Rewrite config log */
 #define LMD_FLG_NOIR		0x0080	/* NO imperative recovery */
 #define LMD_FLG_NOSCRUB		0x0100	/* Do not trigger scrub automatically */
 #define LMD_FLG_MGS		0x0200	/* Also start MGS along with server */
 #define LMD_FLG_IAM		0x0400	/* IAM dir */
 #define LMD_FLG_NO_PRIMNODE	0x0800	/* all nodes are service nodes */
 #define LMD_FLG_VIRGIN		0x1000	/* the service registers first time */
 #define LMD_FLG_UPDATE		0x2000	/* update parameters */
 #define LMD_FLG_HSM		0x4000	/* Start coordinator */

 #define lmd_is_client(x) ((x)->lmd_flags & LMD_FLG_CLIENT)


 /****************** last_rcvd file *********************/

 /** version recovery epoch */
 #define LR_EPOCH_BITS   32
 #define lr_epoch(a) ((a) >> LR_EPOCH_BITS)
 #define LR_EXPIRE_INTERVALS 16 /**< number of intervals to track transno */
 #define ENOENT_VERSION 1 /** 'virtual' version of non-existent object */

 #define LR_SERVER_SIZE   512
 #define LR_CLIENT_START 8192
 #define LR_CLIENT_SIZE   128
 #if LR_CLIENT_START < LR_SERVER_SIZE
 #error "Can't have LR_CLIENT_START < LR_SERVER_SIZE"
 #endif

 /*
  * This limit is arbitrary (131072 clients on x86), but it is convenient to use
  * 2^n * PAGE_CACHE_SIZE * 8 for the number of bits that fit an order-n allocation.
  * If we need more than 131072 clients (order-2 allocation on x86) then this
  * should become an array of single-page pointers that are allocated on demand.
  */
 #if (128 * 1024UL) > (PAGE_CACHE_SIZE * 8)
 #define LR_MAX_CLIENTS (128 * 1024UL)
 #else
 #define LR_MAX_CLIENTS (PAGE_CACHE_SIZE * 8)
 #endif

 /** COMPAT_146: this is an OST (temporary) */
 #define OBD_COMPAT_OST	  0x00000002
 /** COMPAT_146: this is an MDT (temporary) */
 #define OBD_COMPAT_MDT	  0x00000004
 /** 2.0 server, interop flag to show server version is changed */
 #define OBD_COMPAT_20	   0x00000008

 /** MDS handles LOV_OBJID file */
 #define OBD_ROCOMPAT_LOVOBJID   0x00000001

 /** OST handles group subdirs */
 #define OBD_INCOMPAT_GROUPS     0x00000001
 /** this is an OST */
 #define OBD_INCOMPAT_OST	0x00000002
 /** this is an MDT */
 #define OBD_INCOMPAT_MDT	0x00000004
 /** common last_rvcd format */
 #define OBD_INCOMPAT_COMMON_LR  0x00000008
 /** FID is enabled */
 #define OBD_INCOMPAT_FID	0x00000010
 /** Size-on-MDS is enabled */
 #define OBD_INCOMPAT_SOM	0x00000020
 /** filesystem using iam format to store directory entries */
 #define OBD_INCOMPAT_IAM_DIR    0x00000040
 /** LMA attribute contains per-inode incompatible flags */
 #define OBD_INCOMPAT_LMA	0x00000080
 /** lmm_stripe_count has been shrunk from __u32 to __u16 and the remaining 16
  * bits are now used to store a generation. Once we start changing the layout
  * and bumping the generation, old versions expecting a 32-bit lmm_stripe_count
  * will be confused by interpreting stripe_count | gen << 16 as the actual
  * stripe count */
 #define OBD_INCOMPAT_LMM_VER    0x00000100
 /** multiple OI files for MDT */
 #define OBD_INCOMPAT_MULTI_OI   0x00000200

 /* Data stored per server at the head of the last_rcvd file.  In le32 order.
    This should be common to filter_internal.h, lustre_mds.h */
 struct lr_server_data {
 	__u8  lsd_uuid[40];	/* server UUID */
 	__u64 lsd_last_transno;    /* last completed transaction ID */
 	__u64 lsd_compat14;	/* reserved - compat with old last_rcvd */
 	__u64 lsd_mount_count;     /* incarnation number */
 	__u32 lsd_feature_compat;  /* compatible feature flags */
 	__u32 lsd_feature_rocompat;/* read-only compatible feature flags */
 	__u32 lsd_feature_incompat;/* incompatible feature flags */
 	__u32 lsd_server_size;     /* size of server data area */
 	__u32 lsd_client_start;    /* start of per-client data area */
 	__u16 lsd_client_size;     /* size of per-client data area */
 	__u16 lsd_subdir_count;    /* number of subdirectories for objects */
 	__u64 lsd_catalog_oid;     /* recovery catalog object id */
 	__u32 lsd_catalog_ogen;    /* recovery catalog inode generation */
 	__u8  lsd_peeruuid[40];    /* UUID of MDS associated with this OST */
 	__u32 lsd_osd_index;       /* index number of OST in LOV */
 	__u32 lsd_padding1;	/* was lsd_mdt_index, unused in 2.4.0 */
 	__u32 lsd_start_epoch;     /* VBR: start epoch from last boot */
 	/** transaction values since lsd_trans_table_time */
 	__u64 lsd_trans_table[LR_EXPIRE_INTERVALS];
 	/** start point of transno table below */
 	__u32 lsd_trans_table_time; /* time of first slot in table above */
 	__u32 lsd_expire_intervals; /* LR_EXPIRE_INTERVALS */
 	__u8  lsd_padding[LR_SERVER_SIZE - 288];
 };

 /* Data stored per client in the last_rcvd file.  In le32 order. */
 struct lsd_client_data {
 	__u8  lcd_uuid[40];      /* client UUID */
 	__u64 lcd_last_transno; /* last completed transaction ID */
 	__u64 lcd_last_xid;     /* xid for the last transaction */
 	__u32 lcd_last_result;  /* result from last RPC */
 	__u32 lcd_last_data;    /* per-op data (disposition for open &c.) */
 	/* for MDS_CLOSE requests */
 	__u64 lcd_last_close_transno; /* last completed transaction ID */
 	__u64 lcd_last_close_xid;     /* xid for the last transaction */
 	__u32 lcd_last_close_result;  /* result from last RPC */
 	__u32 lcd_last_close_data;    /* per-op data */
 	/* VBR: last versions */
 	__u64 lcd_pre_versions[4];
 	__u32 lcd_last_epoch;
 	/** orphans handling for delayed export rely on that */
 	__u32 lcd_first_epoch;
 	__u8  lcd_padding[LR_CLIENT_SIZE - 128];
 };

 /* bug20354: the lcd_uuid for export of clients may be wrong */
 static inline void check_lcd(char *obd_name, int index,
 			     struct lsd_client_data *lcd)
 {
 	int length = sizeof(lcd->lcd_uuid);
 	if (strnlen((char *)lcd->lcd_uuid, length) == length) {
 		lcd->lcd_uuid[length - 1] = '\0';

 		LCONSOLE_ERROR("the client UUID (%s) on %s for exports stored in last_rcvd(index = %d) is bad!\n",
 			       lcd->lcd_uuid, obd_name, index);
 	}
 }

 /* last_rcvd handling */
 static inline void lsd_le_to_cpu(struct lr_server_data *buf,
 				 struct lr_server_data *lsd)
 {
 	int i;
 	memcpy(lsd->lsd_uuid, buf->lsd_uuid, sizeof(lsd->lsd_uuid));
 	lsd->lsd_last_transno     = le64_to_cpu(buf->lsd_last_transno);
 	lsd->lsd_compat14	 = le64_to_cpu(buf->lsd_compat14);
 	lsd->lsd_mount_count      = le64_to_cpu(buf->lsd_mount_count);
 	lsd->lsd_feature_compat   = le32_to_cpu(buf->lsd_feature_compat);
 	lsd->lsd_feature_rocompat = le32_to_cpu(buf->lsd_feature_rocompat);
 	lsd->lsd_feature_incompat = le32_to_cpu(buf->lsd_feature_incompat);
 	lsd->lsd_server_size      = le32_to_cpu(buf->lsd_server_size);
 	lsd->lsd_client_start     = le32_to_cpu(buf->lsd_client_start);
 	lsd->lsd_client_size      = le16_to_cpu(buf->lsd_client_size);
 	lsd->lsd_subdir_count     = le16_to_cpu(buf->lsd_subdir_count);
 	lsd->lsd_catalog_oid      = le64_to_cpu(buf->lsd_catalog_oid);
 	lsd->lsd_catalog_ogen     = le32_to_cpu(buf->lsd_catalog_ogen);
 	memcpy(lsd->lsd_peeruuid, buf->lsd_peeruuid, sizeof(lsd->lsd_peeruuid));
 	lsd->lsd_osd_index	= le32_to_cpu(buf->lsd_osd_index);
 	lsd->lsd_padding1	= le32_to_cpu(buf->lsd_padding1);
 	lsd->lsd_start_epoch      = le32_to_cpu(buf->lsd_start_epoch);
 	for (i = 0; i < LR_EXPIRE_INTERVALS; i++)
 		lsd->lsd_trans_table[i] = le64_to_cpu(buf->lsd_trans_table[i]);
 	lsd->lsd_trans_table_time = le32_to_cpu(buf->lsd_trans_table_time);
 	lsd->lsd_expire_intervals = le32_to_cpu(buf->lsd_expire_intervals);
 }

 static inline void lsd_cpu_to_le(struct lr_server_data *lsd,
 				 struct lr_server_data *buf)
 {
 	int i;
 	memcpy(buf->lsd_uuid, lsd->lsd_uuid, sizeof(buf->lsd_uuid));
 	buf->lsd_last_transno     = cpu_to_le64(lsd->lsd_last_transno);
 	buf->lsd_compat14	 = cpu_to_le64(lsd->lsd_compat14);
 	buf->lsd_mount_count      = cpu_to_le64(lsd->lsd_mount_count);
 	buf->lsd_feature_compat   = cpu_to_le32(lsd->lsd_feature_compat);
 	buf->lsd_feature_rocompat = cpu_to_le32(lsd->lsd_feature_rocompat);
 	buf->lsd_feature_incompat = cpu_to_le32(lsd->lsd_feature_incompat);
 	buf->lsd_server_size      = cpu_to_le32(lsd->lsd_server_size);
 	buf->lsd_client_start     = cpu_to_le32(lsd->lsd_client_start);
 	buf->lsd_client_size      = cpu_to_le16(lsd->lsd_client_size);
 	buf->lsd_subdir_count     = cpu_to_le16(lsd->lsd_subdir_count);
 	buf->lsd_catalog_oid      = cpu_to_le64(lsd->lsd_catalog_oid);
 	buf->lsd_catalog_ogen     = cpu_to_le32(lsd->lsd_catalog_ogen);
 	memcpy(buf->lsd_peeruuid, lsd->lsd_peeruuid, sizeof(buf->lsd_peeruuid));
 	buf->lsd_osd_index	  = cpu_to_le32(lsd->lsd_osd_index);
 	buf->lsd_padding1	  = cpu_to_le32(lsd->lsd_padding1);
 	buf->lsd_start_epoch      = cpu_to_le32(lsd->lsd_start_epoch);
 	for (i = 0; i < LR_EXPIRE_INTERVALS; i++)
 		buf->lsd_trans_table[i] = cpu_to_le64(lsd->lsd_trans_table[i]);
 	buf->lsd_trans_table_time = cpu_to_le32(lsd->lsd_trans_table_time);
 	buf->lsd_expire_intervals = cpu_to_le32(lsd->lsd_expire_intervals);
 }

 static inline void lcd_le_to_cpu(struct lsd_client_data *buf,
 				 struct lsd_client_data *lcd)
 {
 	memcpy(lcd->lcd_uuid, buf->lcd_uuid, sizeof (lcd->lcd_uuid));
 	lcd->lcd_last_transno       = le64_to_cpu(buf->lcd_last_transno);
 	lcd->lcd_last_xid	   = le64_to_cpu(buf->lcd_last_xid);
 	lcd->lcd_last_result	= le32_to_cpu(buf->lcd_last_result);
 	lcd->lcd_last_data	  = le32_to_cpu(buf->lcd_last_data);
 	lcd->lcd_last_close_transno = le64_to_cpu(buf->lcd_last_close_transno);
 	lcd->lcd_last_close_xid     = le64_to_cpu(buf->lcd_last_close_xid);
 	lcd->lcd_last_close_result  = le32_to_cpu(buf->lcd_last_close_result);
 	lcd->lcd_last_close_data    = le32_to_cpu(buf->lcd_last_close_data);
 	lcd->lcd_pre_versions[0]    = le64_to_cpu(buf->lcd_pre_versions[0]);
 	lcd->lcd_pre_versions[1]    = le64_to_cpu(buf->lcd_pre_versions[1]);
 	lcd->lcd_pre_versions[2]    = le64_to_cpu(buf->lcd_pre_versions[2]);
 	lcd->lcd_pre_versions[3]    = le64_to_cpu(buf->lcd_pre_versions[3]);
 	lcd->lcd_last_epoch	 = le32_to_cpu(buf->lcd_last_epoch);
 	lcd->lcd_first_epoch	= le32_to_cpu(buf->lcd_first_epoch);
 }

 static inline void lcd_cpu_to_le(struct lsd_client_data *lcd,
 				 struct lsd_client_data *buf)
 {
 	memcpy(buf->lcd_uuid, lcd->lcd_uuid, sizeof (lcd->lcd_uuid));
 	buf->lcd_last_transno       = cpu_to_le64(lcd->lcd_last_transno);
 	buf->lcd_last_xid	   = cpu_to_le64(lcd->lcd_last_xid);
 	buf->lcd_last_result	= cpu_to_le32(lcd->lcd_last_result);
 	buf->lcd_last_data	  = cpu_to_le32(lcd->lcd_last_data);
 	buf->lcd_last_close_transno = cpu_to_le64(lcd->lcd_last_close_transno);
 	buf->lcd_last_close_xid     = cpu_to_le64(lcd->lcd_last_close_xid);
 	buf->lcd_last_close_result  = cpu_to_le32(lcd->lcd_last_close_result);
 	buf->lcd_last_close_data    = cpu_to_le32(lcd->lcd_last_close_data);
 	buf->lcd_pre_versions[0]    = cpu_to_le64(lcd->lcd_pre_versions[0]);
 	buf->lcd_pre_versions[1]    = cpu_to_le64(lcd->lcd_pre_versions[1]);
 	buf->lcd_pre_versions[2]    = cpu_to_le64(lcd->lcd_pre_versions[2]);
 	buf->lcd_pre_versions[3]    = cpu_to_le64(lcd->lcd_pre_versions[3]);
 	buf->lcd_last_epoch	 = cpu_to_le32(lcd->lcd_last_epoch);
 	buf->lcd_first_epoch	= cpu_to_le32(lcd->lcd_first_epoch);
 }

 static inline __u64 lcd_last_transno(struct lsd_client_data *lcd)
 {
 	return (lcd->lcd_last_transno > lcd->lcd_last_close_transno ?
 		lcd->lcd_last_transno : lcd->lcd_last_close_transno);
 }

 static inline __u64 lcd_last_xid(struct lsd_client_data *lcd)
 {
 	return (lcd->lcd_last_xid > lcd->lcd_last_close_xid ?
 		lcd->lcd_last_xid : lcd->lcd_last_close_xid);
 }

 /****************** superblock additional info *********************/

 struct ll_sb_info;

 struct lustre_sb_info {
 	int		       lsi_flags;
 	struct obd_device	*lsi_mgc;     /* mgc obd */
 	struct lustre_mount_data *lsi_lmd;     /* mount command info */
 	struct ll_sb_info	*lsi_llsbi;   /* add'l client sbi info */
 	struct dt_device	 *lsi_dt_dev;  /* dt device to access disk fs*/
 	struct vfsmount	  *lsi_srv_mnt; /* the one server mount */
 	atomic_t	      lsi_mounts;  /* references to the srv_mnt */
 	char			  lsi_svname[MTI_NAME_MAXLEN];
 	char			  lsi_osd_obdname[64];
 	char			  lsi_osd_uuid[64];
 	struct obd_export	 *lsi_osd_exp;
 	char			  lsi_osd_type[16];
 	char			  lsi_fstype[16];
 	struct backing_dev_info   lsi_bdi;     /* each client mountpoint needs
 						  own backing_dev_info */
 };

 #define LSI_UMOUNT_FAILOVER	      0x00200000
 #define LSI_BDI_INITIALIZED	      0x00400000

 #define     s2lsi(sb)	((struct lustre_sb_info *)((sb)->s_fs_info))
 #define     s2lsi_nocast(sb) ((sb)->s_fs_info)

 #define     get_profile_name(sb)   (s2lsi(sb)->lsi_lmd->lmd_profile)
 #define	    get_mount_flags(sb)	   (s2lsi(sb)->lsi_lmd->lmd_flags)
 #define	    get_mntdev_name(sb)	   (s2lsi(sb)->lsi_lmd->lmd_dev)


 /****************** mount lookup info *********************/

 struct lustre_mount_info {
 	char		 *lmi_name;
 	struct super_block   *lmi_sb;
 	struct vfsmount      *lmi_mnt;
 	struct list_head	    lmi_list_chain;
 };

 /****************** prototypes *********************/

 /* obd_mount.c */
 int server_name2fsname(const char *svname, char *fsname, const char **endptr);
 int server_name2index(const char *svname, __u32 *idx, const char **endptr);

 int lustre_put_lsi(struct super_block *sb);
 int lustre_start_simple(char *obdname, char *type, char *uuid,
 			char *s1, char *s2, char *s3, char *s4);
 int lustre_start_mgc(struct super_block *sb);
 void lustre_register_client_fill_super(int (*cfs)(struct super_block *sb,
 						  struct vfsmount *mnt));
 void lustre_register_kill_super_cb(void (*cfs)(struct super_block *sb));
 int lustre_common_put_super(struct super_block *sb);


 int mgc_fsname2resid(char *fsname, struct ldlm_res_id *res_id, int type);

 /** @} disk */

 #endif /* _LUSTRE_DISK_H */
	/*
	* GPL HEADER START
	*
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 only,
	* as published by the Free Software Foundation.
	*
	* 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 version 2 for more details (a copy is included
	* in the LICENSE file that accompanied this code).
	*
	* You should have received a copy of the GNU General Public License
	* version 2 along with this program; If not, see
	* http://www.sun.com/software/products/lustre/docs/GPLv2.pdf
	*
	* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
	* CA 95054 USA or visit www.sun.com if you need additional information or
	* have any questions.
	*
	* GPL HEADER END
	*/
	/*
	* Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved.
	* Use is subject to license terms.
	*
	* Copyright (c) 2011, 2012, Intel Corporation.
	*/
	/*
	* This file is part of Lustre, http://www.lustre.org/
	* Lustre is a trademark of Sun Microsystems, Inc.
	*
	* lustre/include/lustre_disk.h
	*
	* Lustre disk format definitions.
	*
	* Author: Nathan Rutman <nathan@clusterfs.com>
	*/

	#ifndef _LUSTRE_DISK_H
	#define _LUSTRE_DISK_H

	/** \defgroup disk disk
	*
	* @{
	*/

	#include "../../include/linux/libcfs/libcfs.h"
	#include "../../include/linux/lnet/types.h"
	#include <linux/backing-dev.h>

	/**************** persistent mount data *******************/

	#define LDD_F_SV_TYPE_MDT 0x0001
	#define LDD_F_SV_TYPE_OST 0x0002
	#define LDD_F_SV_TYPE_MGS 0x0004
	#define LDD_F_SV_TYPE_MASK (LDD_F_SV_TYPE_MDT \| \
	LDD_F_SV_TYPE_OST \| \
	LDD_F_SV_TYPE_MGS)
	#define LDD_F_SV_ALL 0x0008

	/**************** mount command *******************/

	/* The lmd is only used internally by Lustre; mount simply passes
	everything as string options */

	#define LMD_MAGIC 0xbdacbd03

	/* gleaned from the mount command - no persistent info here */
	struct lustre_mount_data {
	__u32 lmd_magic;
	__u32 lmd_flags; /* lustre mount flags */
	int lmd_mgs_failnodes; /* mgs failover node count */
	int lmd_exclude_count;
	int lmd_recovery_time_soft;
	int lmd_recovery_time_hard;
	char lmd_dev; / device name */
	char lmd_profile; / client only */
	char lmd_mgssec; / sptlrpc flavor to mgs */
	char lmd_opts; / lustre mount options (as opposed to
	_device_ mount options) */
	char lmd_params; / lustre params */
	__u32 lmd_exclude; / array of OSTs to ignore */
	char lmd_mgs; / MGS nid */
	char lmd_osd_type; / OSD type */
	};

	#define LMD_FLG_SERVER 0x0001 /* Mounting a server */
	#define LMD_FLG_CLIENT 0x0002 /* Mounting a client */
	#define LMD_FLG_ABORT_RECOV 0x0008 /* Abort recovery */
	#define LMD_FLG_NOSVC 0x0010 /* Only start MGS/MGC for servers,
	no other services */
	#define LMD_FLG_NOMGS 0x0020 /* Only start target for servers, reusing
	existing MGS services */
	#define LMD_FLG_WRITECONF 0x0040 /* Rewrite config log */
	#define LMD_FLG_NOIR 0x0080 /* NO imperative recovery */
	#define LMD_FLG_NOSCRUB 0x0100 /* Do not trigger scrub automatically */
	#define LMD_FLG_MGS 0x0200 /* Also start MGS along with server */
	#define LMD_FLG_IAM 0x0400 /* IAM dir */
	#define LMD_FLG_NO_PRIMNODE 0x0800 /* all nodes are service nodes */
	#define LMD_FLG_VIRGIN 0x1000 /* the service registers first time */
	#define LMD_FLG_UPDATE 0x2000 /* update parameters */
	#define LMD_FLG_HSM 0x4000 /* Start coordinator */

	#define lmd_is_client(x) ((x)->lmd_flags & LMD_FLG_CLIENT)


	/**************** last_rcvd file *******************/

	/** version recovery epoch */
	#define LR_EPOCH_BITS 32
	#define lr_epoch(a) ((a) >> LR_EPOCH_BITS)
	#define LR_EXPIRE_INTERVALS 16 /*< number of intervals to track transno /
	#define ENOENT_VERSION 1 /** 'virtual' version of non-existent object */

	#define LR_SERVER_SIZE 512
	#define LR_CLIENT_START 8192
	#define LR_CLIENT_SIZE 128
	#if LR_CLIENT_START < LR_SERVER_SIZE
	#error "Can't have LR_CLIENT_START < LR_SERVER_SIZE"
	#endif

	/*
	* This limit is arbitrary (131072 clients on x86), but it is convenient to use
	* 2^n * PAGE_CACHE_SIZE * 8 for the number of bits that fit an order-n allocation.
	* If we need more than 131072 clients (order-2 allocation on x86) then this
	* should become an array of single-page pointers that are allocated on demand.
	*/
	#if (128 * 1024UL) > (PAGE_CACHE_SIZE * 8)
	#define LR_MAX_CLIENTS (128 * 1024UL)
	#else
	#define LR_MAX_CLIENTS (PAGE_CACHE_SIZE * 8)
	#endif

	/** COMPAT_146: this is an OST (temporary) */
	#define OBD_COMPAT_OST 0x00000002
	/** COMPAT_146: this is an MDT (temporary) */
	#define OBD_COMPAT_MDT 0x00000004
	/** 2.0 server, interop flag to show server version is changed */
	#define OBD_COMPAT_20 0x00000008

	/** MDS handles LOV_OBJID file */
	#define OBD_ROCOMPAT_LOVOBJID 0x00000001

	/** OST handles group subdirs */
	#define OBD_INCOMPAT_GROUPS 0x00000001
	/** this is an OST */
	#define OBD_INCOMPAT_OST 0x00000002
	/** this is an MDT */
	#define OBD_INCOMPAT_MDT 0x00000004
	/** common last_rvcd format */
	#define OBD_INCOMPAT_COMMON_LR 0x00000008
	/** FID is enabled */
	#define OBD_INCOMPAT_FID 0x00000010
	/** Size-on-MDS is enabled */
	#define OBD_INCOMPAT_SOM 0x00000020
	/** filesystem using iam format to store directory entries */
	#define OBD_INCOMPAT_IAM_DIR 0x00000040
	/** LMA attribute contains per-inode incompatible flags */
	#define OBD_INCOMPAT_LMA 0x00000080
	/** lmm_stripe_count has been shrunk from __u32 to __u16 and the remaining 16
	* bits are now used to store a generation. Once we start changing the layout
	* and bumping the generation, old versions expecting a 32-bit lmm_stripe_count
	* will be confused by interpreting stripe_count \| gen << 16 as the actual
	* stripe count */
	#define OBD_INCOMPAT_LMM_VER 0x00000100
	/** multiple OI files for MDT */
	#define OBD_INCOMPAT_MULTI_OI 0x00000200

	/* Data stored per server at the head of the last_rcvd file. In le32 order.
	This should be common to filter_internal.h, lustre_mds.h */
	struct lr_server_data {
	__u8 lsd_uuid[40]; /* server UUID */
	__u64 lsd_last_transno; /* last completed transaction ID */
	__u64 lsd_compat14; /* reserved - compat with old last_rcvd */
	__u64 lsd_mount_count; /* incarnation number */
	__u32 lsd_feature_compat; /* compatible feature flags */
	__u32 lsd_feature_rocompat;/* read-only compatible feature flags */
	__u32 lsd_feature_incompat;/* incompatible feature flags */
	__u32 lsd_server_size; /* size of server data area */
	__u32 lsd_client_start; /* start of per-client data area */
	__u16 lsd_client_size; /* size of per-client data area */
	__u16 lsd_subdir_count; /* number of subdirectories for objects */
	__u64 lsd_catalog_oid; /* recovery catalog object id */
	__u32 lsd_catalog_ogen; /* recovery catalog inode generation */
	__u8 lsd_peeruuid[40]; /* UUID of MDS associated with this OST */
	__u32 lsd_osd_index; /* index number of OST in LOV */
	__u32 lsd_padding1; /* was lsd_mdt_index, unused in 2.4.0 */
	__u32 lsd_start_epoch; /* VBR: start epoch from last boot */
	/** transaction values since lsd_trans_table_time */
	__u64 lsd_trans_table[LR_EXPIRE_INTERVALS];
	/** start point of transno table below */
	__u32 lsd_trans_table_time; /* time of first slot in table above */
	__u32 lsd_expire_intervals; /* LR_EXPIRE_INTERVALS */
	__u8 lsd_padding[LR_SERVER_SIZE - 288];
	};

	/* Data stored per client in the last_rcvd file. In le32 order. */
	struct lsd_client_data {
	__u8 lcd_uuid[40]; /* client UUID */
	__u64 lcd_last_transno; /* last completed transaction ID */
	__u64 lcd_last_xid; /* xid for the last transaction */
	__u32 lcd_last_result; /* result from last RPC */
	__u32 lcd_last_data; /* per-op data (disposition for open &c.) */
	/* for MDS_CLOSE requests */
	__u64 lcd_last_close_transno; /* last completed transaction ID */
	__u64 lcd_last_close_xid; /* xid for the last transaction */
	__u32 lcd_last_close_result; /* result from last RPC */
	__u32 lcd_last_close_data; /* per-op data */
	/* VBR: last versions */
	__u64 lcd_pre_versions[4];
	__u32 lcd_last_epoch;
	/** orphans handling for delayed export rely on that */
	__u32 lcd_first_epoch;
	__u8 lcd_padding[LR_CLIENT_SIZE - 128];
	};

	/* bug20354: the lcd_uuid for export of clients may be wrong */
	static inline void check_lcd(char *obd_name, int index,
	struct lsd_client_data *lcd)
	{
	int length = sizeof(lcd->lcd_uuid);
	if (strnlen((char *)lcd->lcd_uuid, length) == length) {
	lcd->lcd_uuid[length - 1] = '\0';

	LCONSOLE_ERROR("the client UUID (%s) on %s for exports stored in last_rcvd(index = %d) is bad!\n",
	lcd->lcd_uuid, obd_name, index);
	}
	}

	/* last_rcvd handling */
	static inline void lsd_le_to_cpu(struct lr_server_data *buf,
	struct lr_server_data *lsd)
	{
	int i;
	memcpy(lsd->lsd_uuid, buf->lsd_uuid, sizeof(lsd->lsd_uuid));
	lsd->lsd_last_transno = le64_to_cpu(buf->lsd_last_transno);
	lsd->lsd_compat14 = le64_to_cpu(buf->lsd_compat14);
	lsd->lsd_mount_count = le64_to_cpu(buf->lsd_mount_count);
	lsd->lsd_feature_compat = le32_to_cpu(buf->lsd_feature_compat);
	lsd->lsd_feature_rocompat = le32_to_cpu(buf->lsd_feature_rocompat);
	lsd->lsd_feature_incompat = le32_to_cpu(buf->lsd_feature_incompat);
	lsd->lsd_server_size = le32_to_cpu(buf->lsd_server_size);
	lsd->lsd_client_start = le32_to_cpu(buf->lsd_client_start);
	lsd->lsd_client_size = le16_to_cpu(buf->lsd_client_size);
	lsd->lsd_subdir_count = le16_to_cpu(buf->lsd_subdir_count);
	lsd->lsd_catalog_oid = le64_to_cpu(buf->lsd_catalog_oid);
	lsd->lsd_catalog_ogen = le32_to_cpu(buf->lsd_catalog_ogen);
	memcpy(lsd->lsd_peeruuid, buf->lsd_peeruuid, sizeof(lsd->lsd_peeruuid));
	lsd->lsd_osd_index = le32_to_cpu(buf->lsd_osd_index);
	lsd->lsd_padding1 = le32_to_cpu(buf->lsd_padding1);
	lsd->lsd_start_epoch = le32_to_cpu(buf->lsd_start_epoch);
	for (i = 0; i < LR_EXPIRE_INTERVALS; i++)
	lsd->lsd_trans_table[i] = le64_to_cpu(buf->lsd_trans_table[i]);
	lsd->lsd_trans_table_time = le32_to_cpu(buf->lsd_trans_table_time);
	lsd->lsd_expire_intervals = le32_to_cpu(buf->lsd_expire_intervals);
	}

	static inline void lsd_cpu_to_le(struct lr_server_data *lsd,
	struct lr_server_data *buf)
	{
	int i;
	memcpy(buf->lsd_uuid, lsd->lsd_uuid, sizeof(buf->lsd_uuid));
	buf->lsd_last_transno = cpu_to_le64(lsd->lsd_last_transno);
	buf->lsd_compat14 = cpu_to_le64(lsd->lsd_compat14);
	buf->lsd_mount_count = cpu_to_le64(lsd->lsd_mount_count);
	buf->lsd_feature_compat = cpu_to_le32(lsd->lsd_feature_compat);
	buf->lsd_feature_rocompat = cpu_to_le32(lsd->lsd_feature_rocompat);
	buf->lsd_feature_incompat = cpu_to_le32(lsd->lsd_feature_incompat);
	buf->lsd_server_size = cpu_to_le32(lsd->lsd_server_size);
	buf->lsd_client_start = cpu_to_le32(lsd->lsd_client_start);
	buf->lsd_client_size = cpu_to_le16(lsd->lsd_client_size);
	buf->lsd_subdir_count = cpu_to_le16(lsd->lsd_subdir_count);
	buf->lsd_catalog_oid = cpu_to_le64(lsd->lsd_catalog_oid);
	buf->lsd_catalog_ogen = cpu_to_le32(lsd->lsd_catalog_ogen);
	memcpy(buf->lsd_peeruuid, lsd->lsd_peeruuid, sizeof(buf->lsd_peeruuid));
	buf->lsd_osd_index = cpu_to_le32(lsd->lsd_osd_index);
	buf->lsd_padding1 = cpu_to_le32(lsd->lsd_padding1);
	buf->lsd_start_epoch = cpu_to_le32(lsd->lsd_start_epoch);
	for (i = 0; i < LR_EXPIRE_INTERVALS; i++)
	buf->lsd_trans_table[i] = cpu_to_le64(lsd->lsd_trans_table[i]);
	buf->lsd_trans_table_time = cpu_to_le32(lsd->lsd_trans_table_time);
	buf->lsd_expire_intervals = cpu_to_le32(lsd->lsd_expire_intervals);
	}

	static inline void lcd_le_to_cpu(struct lsd_client_data *buf,
	struct lsd_client_data *lcd)
	{
	memcpy(lcd->lcd_uuid, buf->lcd_uuid, sizeof (lcd->lcd_uuid));
	lcd->lcd_last_transno = le64_to_cpu(buf->lcd_last_transno);
	lcd->lcd_last_xid = le64_to_cpu(buf->lcd_last_xid);
	lcd->lcd_last_result = le32_to_cpu(buf->lcd_last_result);
	lcd->lcd_last_data = le32_to_cpu(buf->lcd_last_data);
	lcd->lcd_last_close_transno = le64_to_cpu(buf->lcd_last_close_transno);
	lcd->lcd_last_close_xid = le64_to_cpu(buf->lcd_last_close_xid);
	lcd->lcd_last_close_result = le32_to_cpu(buf->lcd_last_close_result);
	lcd->lcd_last_close_data = le32_to_cpu(buf->lcd_last_close_data);
	lcd->lcd_pre_versions[0] = le64_to_cpu(buf->lcd_pre_versions[0]);
	lcd->lcd_pre_versions[1] = le64_to_cpu(buf->lcd_pre_versions[1]);
	lcd->lcd_pre_versions[2] = le64_to_cpu(buf->lcd_pre_versions[2]);
	lcd->lcd_pre_versions[3] = le64_to_cpu(buf->lcd_pre_versions[3]);
	lcd->lcd_last_epoch = le32_to_cpu(buf->lcd_last_epoch);
	lcd->lcd_first_epoch = le32_to_cpu(buf->lcd_first_epoch);
	}

	static inline void lcd_cpu_to_le(struct lsd_client_data *lcd,
	struct lsd_client_data *buf)
	{
	memcpy(buf->lcd_uuid, lcd->lcd_uuid, sizeof (lcd->lcd_uuid));
	buf->lcd_last_transno = cpu_to_le64(lcd->lcd_last_transno);
	buf->lcd_last_xid = cpu_to_le64(lcd->lcd_last_xid);
	buf->lcd_last_result = cpu_to_le32(lcd->lcd_last_result);
	buf->lcd_last_data = cpu_to_le32(lcd->lcd_last_data);
	buf->lcd_last_close_transno = cpu_to_le64(lcd->lcd_last_close_transno);
	buf->lcd_last_close_xid = cpu_to_le64(lcd->lcd_last_close_xid);
	buf->lcd_last_close_result = cpu_to_le32(lcd->lcd_last_close_result);
	buf->lcd_last_close_data = cpu_to_le32(lcd->lcd_last_close_data);
	buf->lcd_pre_versions[0] = cpu_to_le64(lcd->lcd_pre_versions[0]);
	buf->lcd_pre_versions[1] = cpu_to_le64(lcd->lcd_pre_versions[1]);
	buf->lcd_pre_versions[2] = cpu_to_le64(lcd->lcd_pre_versions[2]);
	buf->lcd_pre_versions[3] = cpu_to_le64(lcd->lcd_pre_versions[3]);
	buf->lcd_last_epoch = cpu_to_le32(lcd->lcd_last_epoch);
	buf->lcd_first_epoch = cpu_to_le32(lcd->lcd_first_epoch);
	}

	static inline __u64 lcd_last_transno(struct lsd_client_data *lcd)
	{
	return (lcd->lcd_last_transno > lcd->lcd_last_close_transno ?
	lcd->lcd_last_transno : lcd->lcd_last_close_transno);
	}

	static inline __u64 lcd_last_xid(struct lsd_client_data *lcd)
	{
	return (lcd->lcd_last_xid > lcd->lcd_last_close_xid ?
	lcd->lcd_last_xid : lcd->lcd_last_close_xid);
	}

	/**************** superblock additional info *******************/

	struct ll_sb_info;

	struct lustre_sb_info {
	int lsi_flags;
	struct obd_device lsi_mgc; / mgc obd */
	struct lustre_mount_data lsi_lmd; / mount command info */
	struct ll_sb_info lsi_llsbi; / add'l client sbi info */
	struct dt_device lsi_dt_dev; / dt device to access disk fs*/
	struct vfsmount lsi_srv_mnt; / the one server mount */
	atomic_t lsi_mounts; /* references to the srv_mnt */
	char lsi_svname[MTI_NAME_MAXLEN];
	char lsi_osd_obdname[64];
	char lsi_osd_uuid[64];
	struct obd_export *lsi_osd_exp;
	char lsi_osd_type[16];
	char lsi_fstype[16];
	struct backing_dev_info lsi_bdi; /* each client mountpoint needs
	own backing_dev_info */
	};

	#define LSI_UMOUNT_FAILOVER 0x00200000
	#define LSI_BDI_INITIALIZED 0x00400000

	#define s2lsi(sb) ((struct lustre_sb_info *)((sb)->s_fs_info))
	#define s2lsi_nocast(sb) ((sb)->s_fs_info)

	#define get_profile_name(sb) (s2lsi(sb)->lsi_lmd->lmd_profile)
	#define get_mount_flags(sb) (s2lsi(sb)->lsi_lmd->lmd_flags)
	#define get_mntdev_name(sb) (s2lsi(sb)->lsi_lmd->lmd_dev)


	/**************** mount lookup info *******************/

	struct lustre_mount_info {
	char *lmi_name;
	struct super_block *lmi_sb;
	struct vfsmount *lmi_mnt;
	struct list_head lmi_list_chain;
	};

	/**************** prototypes *******************/

	/* obd_mount.c */
	int server_name2fsname(const char svname, char fsname, const char **endptr);
	int server_name2index(const char svname, __u32 idx, const char **endptr);

	int lustre_put_lsi(struct super_block *sb);
	int lustre_start_simple(char obdname, char type, char *uuid,
	char s1, char s2, char s3, char s4);
	int lustre_start_mgc(struct super_block *sb);
	void lustre_register_client_fill_super(int (cfs)(struct super_block sb,
	struct vfsmount *mnt));
	void lustre_register_kill_super_cb(void (cfs)(struct super_block sb));
	int lustre_common_put_super(struct super_block *sb);


	int mgc_fsname2resid(char fsname, struct ldlm_res_id res_id, int type);

	/** @} disk */

	#endif /* _LUSTRE_DISK_H */