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freebsd/sys/fs/nandfs/nandfs_fs.h
Grzegorz Bernacki 7f725bcd5c Import work done under project/nand (@235533) into head.
The NAND Flash environment consists of several distinct components:
  - NAND framework (drivers harness for NAND controllers and NAND chips)
  - NAND simulator (NANDsim)
  - NAND file system (NAND FS)
  - Companion tools and utilities
  - Documentation (manual pages)

This work is still experimental. Please use with caution.

Obtained from: Semihalf
Supported by:  FreeBSD Foundation, Juniper Networks
2012-05-17 10:11:18 +00:00

566 lines
18 KiB
C

/*-
* Copyright (c) 2010-2012 Semihalf
* Copyright (c) 2008, 2009 Reinoud Zandijk
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Original definitions written by Koji Sato <koji@osrg.net>
* and Ryusuke Konishi <ryusuke@osrg.net>
* From: NetBSD: nandfs_fs.h,v 1.1 2009/07/18 16:31:42 reinoud
*
* $FreeBSD$
*/
#ifndef _NANDFS_FS_H
#define _NANDFS_FS_H
#include <sys/uuid.h>
#define MNINDIR(fsdev) ((fsdev)->nd_blocksize / sizeof(nandfs_daddr_t))
/*
* Inode structure. There are a few dedicated inode numbers that are
* defined here first.
*/
#define NANDFS_WHT_INO 1 /* Whiteout ino */
#define NANDFS_ROOT_INO 2 /* Root file inode */
#define NANDFS_DAT_INO 3 /* DAT file */
#define NANDFS_CPFILE_INO 4 /* checkpoint file */
#define NANDFS_SUFILE_INO 5 /* segment usage file */
#define NANDFS_IFILE_INO 6 /* ifile */
#define NANDFS_GC_INO 7 /* Cleanerd node */
#define NANDFS_ATIME_INO 8 /* Atime file (reserved) */
#define NANDFS_XATTR_INO 9 /* Xattribute file (reserved) */
#define NANDFS_SKETCH_INO 10 /* Sketch file (obsolete) */
#define NANDFS_USER_INO 11 /* First user's file inode number */
#define NANDFS_SYS_NODE(ino) \
(((ino) >= NANDFS_DAT_INO) && ((ino) <= NANDFS_GC_INO))
#define NDADDR 12 /* Direct addresses in inode. */
#define NIADDR 3 /* Indirect addresses in inode. */
typedef int64_t nandfs_daddr_t;
typedef int64_t nandfs_lbn_t;
struct nandfs_inode {
uint64_t i_blocks; /* 0: size in device blocks */
uint64_t i_size; /* 8: size in bytes */
uint64_t i_ctime; /* 16: creation time in seconds */
uint64_t i_mtime; /* 24: modification time in seconds part*/
uint32_t i_ctime_nsec; /* 32: creation time nanoseconds part */
uint32_t i_mtime_nsec; /* 36: modification time in nanoseconds */
uint32_t i_uid; /* 40: user id */
uint32_t i_gid; /* 44: group id */
uint16_t i_mode; /* 48: file mode */
uint16_t i_links_count; /* 50: number of references to the inode*/
uint32_t i_flags; /* 52: NANDFS_*_FL flags */
nandfs_daddr_t i_special; /* 56: special */
nandfs_daddr_t i_db[NDADDR]; /* 64: Direct disk blocks. */
nandfs_daddr_t i_ib[NIADDR]; /* 160: Indirect disk blocks. */
uint64_t i_xattr; /* 184: reserved for extended attributes*/
uint32_t i_generation; /* 192: file generation for NFS */
uint32_t i_pad[15]; /* 196: make it 64 bits aligned */
};
#ifdef _KERNEL
CTASSERT(sizeof(struct nandfs_inode) == 256);
#endif
/*
* Each checkpoint/snapshot has a super root.
*
* The super root holds the inodes of the three system files: `dat', `cp' and
* 'su' files. All other FS state is defined by those.
*
* It is CRC checksum'ed and time stamped.
*/
struct nandfs_super_root {
uint32_t sr_sum; /* check-sum */
uint16_t sr_bytes; /* byte count of this structure */
uint16_t sr_flags; /* reserved for flags */
uint64_t sr_nongc_ctime; /* timestamp, not for cleaner(?) */
struct nandfs_inode sr_dat; /* DAT, virt->phys translation inode */
struct nandfs_inode sr_cpfile; /* CP, checkpoints inode */
struct nandfs_inode sr_sufile; /* SU, segment usage inode */
};
#define NANDFS_SR_MDT_OFFSET(inode_size, i) \
((uint32_t)&((struct nandfs_super_root *)0)->sr_dat + \
(inode_size) * (i))
#define NANDFS_SR_DAT_OFFSET(inode_size) NANDFS_SR_MDT_OFFSET(inode_size, 0)
#define NANDFS_SR_CPFILE_OFFSET(inode_size) NANDFS_SR_MDT_OFFSET(inode_size, 1)
#define NANDFS_SR_SUFILE_OFFSET(inode_size) NANDFS_SR_MDT_OFFSET(inode_size, 2)
#define NANDFS_SR_BYTES (sizeof(struct nandfs_super_root))
/*
* The superblock describes the basic structure and mount history. It also
* records some sizes of structures found on the disc for sanity checks.
*
* The superblock is stored at two places: NANDFS_SB_OFFSET_BYTES and
* NANDFS_SB2_OFFSET_BYTES.
*/
/* File system states stored on media in superblock's sbp->s_state */
#define NANDFS_VALID_FS 0x0001 /* cleanly unmounted and all is ok */
#define NANDFS_ERROR_FS 0x0002 /* there were errors detected, fsck */
#define NANDFS_RESIZE_FS 0x0004 /* resize required, XXX unknown flag*/
#define NANDFS_MOUNT_STATE_BITS "\20\1VALID_FS\2ERROR_FS\3RESIZE_FS"
/*
* Brief description of control structures:
*
* NANDFS_NFSAREAS first blocks contain fsdata and some amount of super blocks.
* Simple round-robin policy is used in order to choose which block will
* contain new super block.
*
* Simple case with 2 blocks:
* 1: fsdata sblock1 [sblock3 [sblock5 ..]]
* 2: fsdata sblock2 [sblock4 [sblock6 ..]]
*/
struct nandfs_fsdata {
uint16_t f_magic;
uint16_t f_bytes;
uint32_t f_sum; /* checksum of fsdata */
uint32_t f_rev_level; /* major disk format revision */
uint64_t f_ctime; /* creation time (execution time
of newfs) */
/* Block size represented as: blocksize = 1 << (f_log_block_size + 10) */
uint32_t f_log_block_size;
uint16_t f_inode_size; /* size of an inode */
uint16_t f_dat_entry_size; /* size of a dat entry */
uint16_t f_checkpoint_size; /* size of a checkpoint */
uint16_t f_segment_usage_size; /* size of a segment usage */
uint16_t f_sbbytes; /* byte count of CRC calculation
for super blocks. s_reserved
is excluded! */
uint16_t f_errors; /* behaviour on detecting errors */
uint32_t f_erasesize;
uint64_t f_nsegments; /* number of segm. in filesystem */
nandfs_daddr_t f_first_data_block; /* 1st seg disk block number */
uint32_t f_blocks_per_segment; /* number of blocks per segment */
uint32_t f_r_segments_percentage; /* reserved segments percentage */
struct uuid f_uuid; /* 128-bit uuid for volume */
char f_volume_name[16]; /* volume name */
uint32_t f_pad[104];
} __packed;
#ifdef _KERNEL
CTASSERT(sizeof(struct nandfs_fsdata) == 512);
#endif
struct nandfs_super_block {
uint16_t s_magic; /* magic value for identification */
uint32_t s_sum; /* check sum of super block */
uint64_t s_last_cno; /* last checkpoint number */
uint64_t s_last_pseg; /* addr part. segm. written last */
uint64_t s_last_seq; /* seq.number of seg written last */
uint64_t s_free_blocks_count; /* free blocks count */
uint64_t s_mtime; /* mount time */
uint64_t s_wtime; /* write time */
uint16_t s_state; /* file system state */
char s_last_mounted[64]; /* directory where last mounted */
uint32_t s_c_interval; /* commit interval of segment */
uint32_t s_c_block_max; /* threshold of data amount for
the segment construction */
uint32_t s_reserved[32]; /* padding to end of the block */
} __packed;
#ifdef _KERNEL
CTASSERT(sizeof(struct nandfs_super_block) == 256);
#endif
#define NANDFS_FSDATA_MAGIC 0xf8da
#define NANDFS_SUPER_MAGIC 0x8008
#define NANDFS_NFSAREAS 4
#define NANDFS_DATA_OFFSET_BYTES(esize) (NANDFS_NFSAREAS * (esize))
#define NANDFS_SBLOCK_OFFSET_BYTES (sizeof(struct nandfs_fsdata))
#define NANDFS_DEF_BLOCKSIZE 4096
#define NANDFS_MIN_BLOCKSIZE 512
#define NANDFS_DEF_ERASESIZE (2 << 16)
#define NANDFS_MIN_SEGSIZE NANDFS_DEF_ERASESIZE
#define NANDFS_CURRENT_REV 9 /* current major revision */
#define NANDFS_FSDATA_CRC_BYTES offsetof(struct nandfs_fsdata, f_pad)
/* Bytes count of super_block for CRC-calculation */
#define NANDFS_SB_BYTES offsetof(struct nandfs_super_block, s_reserved)
/* Maximal count of links to a file */
#define NANDFS_LINK_MAX 32000
/*
* Structure of a directory entry.
*
* Note that they can't span blocks; the rec_len fills out.
*/
#define NANDFS_NAME_LEN 255
struct nandfs_dir_entry {
uint64_t inode; /* inode number */
uint16_t rec_len; /* directory entry length */
uint8_t name_len; /* name length */
uint8_t file_type;
char name[NANDFS_NAME_LEN]; /* file name */
char pad;
};
/*
* NANDFS_DIR_PAD defines the directory entries boundaries
*
* NOTE: It must be a multiple of 8
*/
#define NANDFS_DIR_PAD 8
#define NANDFS_DIR_ROUND (NANDFS_DIR_PAD - 1)
#define NANDFS_DIR_NAME_OFFSET (offsetof(struct nandfs_dir_entry, name))
#define NANDFS_DIR_REC_LEN(name_len) \
(((name_len) + NANDFS_DIR_NAME_OFFSET + NANDFS_DIR_ROUND) \
& ~NANDFS_DIR_ROUND)
#define NANDFS_DIR_NAME_LEN(name_len) \
(NANDFS_DIR_REC_LEN(name_len) - NANDFS_DIR_NAME_OFFSET)
/*
* NiLFS/NANDFS devides the disc into fixed length segments. Each segment is
* filled with one or more partial segments of variable lengths.
*
* Each partial segment has a segment summary header followed by updates of
* files and optionally a super root.
*/
/*
* Virtual to physical block translation information. For data blocks it maps
* logical block number bi_blkoff to virtual block nr bi_vblocknr. For non
* datablocks it is the virtual block number assigned to an indirect block
* and has no bi_blkoff. The physical block number is the next
* available data block in the partial segment after all the binfo's.
*/
struct nandfs_binfo_v {
uint64_t bi_ino; /* file's inode */
uint64_t bi_vblocknr; /* assigned virtual block number */
uint64_t bi_blkoff; /* for file's logical block number */
};
/*
* DAT allocation. For data blocks just the logical block number that maps on
* the next available data block in the partial segment after the binfo's.
*/
struct nandfs_binfo_dat {
uint64_t bi_ino;
uint64_t bi_blkoff; /* DAT file's logical block number */
uint8_t bi_level; /* whether this is meta block */
uint8_t bi_pad[7];
};
#ifdef _KERNEL
CTASSERT(sizeof(struct nandfs_binfo_v) == sizeof(struct nandfs_binfo_dat));
#endif
/* Convenience union for both types of binfo's */
union nandfs_binfo {
struct nandfs_binfo_v bi_v;
struct nandfs_binfo_dat bi_dat;
};
/* Indirect buffers path */
struct nandfs_indir {
nandfs_daddr_t in_lbn;
int in_off;
};
/* The (partial) segment summary */
struct nandfs_segment_summary {
uint32_t ss_datasum; /* CRC of complete data block */
uint32_t ss_sumsum; /* CRC of segment summary only */
uint32_t ss_magic; /* magic to identify segment summary */
uint16_t ss_bytes; /* size of segment summary structure */
uint16_t ss_flags; /* NANDFS_SS_* flags */
uint64_t ss_seq; /* sequence number of this segm. sum */
uint64_t ss_create; /* creation timestamp in seconds */
uint64_t ss_next; /* blocknumber of next segment */
uint32_t ss_nblocks; /* number of blocks used by summary */
uint32_t ss_nbinfos; /* number of binfo structures */
uint32_t ss_sumbytes; /* total size of segment summary */
uint32_t ss_pad;
/* stream of binfo structures */
};
#define NANDFS_SEGSUM_MAGIC 0x8e680011 /* segment summary magic number */
/* Segment summary flags */
#define NANDFS_SS_LOGBGN 0x0001 /* begins a logical segment */
#define NANDFS_SS_LOGEND 0x0002 /* ends a logical segment */
#define NANDFS_SS_SR 0x0004 /* has super root */
#define NANDFS_SS_SYNDT 0x0008 /* includes data only updates */
#define NANDFS_SS_GC 0x0010 /* segment written for cleaner operation */
#define NANDFS_SS_FLAG_BITS "\20\1LOGBGN\2LOGEND\3SR\4SYNDT\5GC"
/* Segment summary constrains */
#define NANDFS_SEG_MIN_BLOCKS 16 /* minimum number of blocks in a
full segment */
#define NANDFS_PSEG_MIN_BLOCKS 2 /* minimum number of blocks in a
partial segment */
#define NANDFS_MIN_NRSVSEGS 8 /* minimum number of reserved
segments */
/*
* Structure of DAT/inode file.
*
* A DAT file is devided into groups. The maximum number of groups is the
* number of block group descriptors that fit into one block; this descriptor
* only gives the number of free entries in the associated group.
*
* Each group has a block sized bitmap indicating if an entry is taken or
* empty. Each bit stands for a DAT entry.
*
* The inode file has exactly the same format only the entries are inode
* entries.
*/
struct nandfs_block_group_desc {
uint32_t bg_nfrees; /* num. free entries in block group */
};
/* DAT entry in a super root's DAT file */
struct nandfs_dat_entry {
uint64_t de_blocknr; /* block number */
uint64_t de_start; /* valid from checkpoint */
uint64_t de_end; /* valid till checkpoint */
uint64_t de_rsv; /* reserved for future use */
};
/*
* Structure of CP file.
*
* A snapshot is just a checkpoint only it's protected against removal by the
* cleaner. The snapshots are kept on a double linked list of checkpoints.
*/
struct nandfs_snapshot_list {
uint64_t ssl_next; /* checkpoint nr. forward */
uint64_t ssl_prev; /* checkpoint nr. back */
};
/* Checkpoint entry structure */
struct nandfs_checkpoint {
uint32_t cp_flags; /* NANDFS_CHECKPOINT_* flags */
uint32_t cp_checkpoints_count; /* ZERO, not used anymore? */
struct nandfs_snapshot_list cp_snapshot_list; /* list of snapshots */
uint64_t cp_cno; /* checkpoint number */
uint64_t cp_create; /* creation timestamp */
uint64_t cp_nblk_inc; /* number of blocks incremented */
uint64_t cp_blocks_count; /* reserved (might be deleted) */
struct nandfs_inode cp_ifile_inode; /* inode file inode */
};
/* Checkpoint flags */
#define NANDFS_CHECKPOINT_SNAPSHOT 1
#define NANDFS_CHECKPOINT_INVALID 2
#define NANDFS_CHECKPOINT_SKETCH 4
#define NANDFS_CHECKPOINT_MINOR 8
#define NANDFS_CHECKPOINT_BITS "\20\1SNAPSHOT\2INVALID\3SKETCH\4MINOR"
/* Header of the checkpoint file */
struct nandfs_cpfile_header {
uint64_t ch_ncheckpoints; /* number of checkpoints */
uint64_t ch_nsnapshots; /* number of snapshots */
struct nandfs_snapshot_list ch_snapshot_list; /* snapshot list */
};
#define NANDFS_CPFILE_FIRST_CHECKPOINT_OFFSET \
((sizeof(struct nandfs_cpfile_header) + \
sizeof(struct nandfs_checkpoint) - 1) / \
sizeof(struct nandfs_checkpoint))
#define NANDFS_NOSEGMENT 0xffffffff
/*
* Structure of SU file.
*
* The segment usage file sums up how each of the segments are used. They are
* indexed by their segment number.
*/
/* Segment usage entry */
struct nandfs_segment_usage {
uint64_t su_lastmod; /* last modified timestamp */
uint32_t su_nblocks; /* number of blocks in segment */
uint32_t su_flags; /* NANDFS_SEGMENT_USAGE_* flags */
};
/* Segment usage flag */
#define NANDFS_SEGMENT_USAGE_ACTIVE 1
#define NANDFS_SEGMENT_USAGE_DIRTY 2
#define NANDFS_SEGMENT_USAGE_ERROR 4
#define NANDFS_SEGMENT_USAGE_GC 8
#define NANDFS_SEGMENT_USAGE_BITS "\20\1ACTIVE\2DIRTY\3ERROR"
/* Header of the segment usage file */
struct nandfs_sufile_header {
uint64_t sh_ncleansegs; /* number of segments marked clean */
uint64_t sh_ndirtysegs; /* number of segments marked dirty */
uint64_t sh_last_alloc; /* last allocated segment number */
};
#define NANDFS_SUFILE_FIRST_SEGMENT_USAGE_OFFSET \
((sizeof(struct nandfs_sufile_header) + \
sizeof(struct nandfs_segment_usage) - 1) / \
sizeof(struct nandfs_segment_usage))
struct nandfs_seg_stat {
uint64_t nss_nsegs;
uint64_t nss_ncleansegs;
uint64_t nss_ndirtysegs;
uint64_t nss_ctime;
uint64_t nss_nongc_ctime;
uint64_t nss_prot_seq;
};
enum {
NANDFS_CHECKPOINT,
NANDFS_SNAPSHOT
};
#define NANDFS_CPINFO_MAX 512
struct nandfs_cpinfo {
uint32_t nci_flags;
uint32_t nci_pad;
uint64_t nci_cno;
uint64_t nci_create;
uint64_t nci_nblk_inc;
uint64_t nci_blocks_count;
uint64_t nci_next;
};
#define NANDFS_SEGMENTS_MAX 512
struct nandfs_suinfo {
uint64_t nsi_num;
uint64_t nsi_lastmod;
uint32_t nsi_blocks;
uint32_t nsi_flags;
};
#define NANDFS_VINFO_MAX 512
struct nandfs_vinfo {
uint64_t nvi_ino;
uint64_t nvi_vblocknr;
uint64_t nvi_start;
uint64_t nvi_end;
uint64_t nvi_blocknr;
int nvi_alive;
};
struct nandfs_cpmode {
uint64_t ncpm_cno;
uint32_t ncpm_mode;
uint32_t ncpm_pad;
};
struct nandfs_argv {
uint64_t nv_base;
uint32_t nv_nmembs;
uint16_t nv_size;
uint16_t nv_flags;
uint64_t nv_index;
};
struct nandfs_cpstat {
uint64_t ncp_cno;
uint64_t ncp_ncps;
uint64_t ncp_nss;
};
struct nandfs_period {
uint64_t p_start;
uint64_t p_end;
};
struct nandfs_vdesc {
uint64_t vd_ino;
uint64_t vd_cno;
uint64_t vd_vblocknr;
struct nandfs_period vd_period;
uint64_t vd_blocknr;
uint64_t vd_offset;
uint32_t vd_flags;
uint32_t vd_pad;
};
struct nandfs_bdesc {
uint64_t bd_ino;
uint64_t bd_oblocknr;
uint64_t bd_blocknr;
uint64_t bd_offset;
uint32_t bd_level;
uint32_t bd_alive;
};
#ifndef _KERNEL
#ifndef MNAMELEN
#define MNAMELEN 88
#endif
#endif
struct nandfs_fsinfo {
struct nandfs_fsdata fs_fsdata;
struct nandfs_super_block fs_super;
char fs_dev[MNAMELEN];
};
#define NANDFS_MAX_MOUNTS 65535
#define NANDFS_IOCTL_GET_SUSTAT _IOR('N', 100, struct nandfs_seg_stat)
#define NANDFS_IOCTL_CHANGE_CPMODE _IOWR('N', 101, struct nandfs_cpmode)
#define NANDFS_IOCTL_GET_CPINFO _IOWR('N', 102, struct nandfs_argv)
#define NANDFS_IOCTL_DELETE_CP _IOWR('N', 103, uint64_t[2])
#define NANDFS_IOCTL_GET_CPSTAT _IOR('N', 104, struct nandfs_cpstat)
#define NANDFS_IOCTL_GET_SUINFO _IOWR('N', 105, struct nandfs_argv)
#define NANDFS_IOCTL_GET_VINFO _IOWR('N', 106, struct nandfs_argv)
#define NANDFS_IOCTL_GET_BDESCS _IOWR('N', 107, struct nandfs_argv)
#define NANDFS_IOCTL_GET_FSINFO _IOR('N', 108, struct nandfs_fsinfo)
#define NANDFS_IOCTL_MAKE_SNAP _IOWR('N', 109, uint64_t)
#define NANDFS_IOCTL_DELETE_SNAP _IOWR('N', 110, uint64_t)
#define NANDFS_IOCTL_SYNC _IOWR('N', 111, uint64_t)
#endif /* _NANDFS_FS_H */