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super-ddf.c
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super-ddf.c
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/*
* mdadm - manage Linux "md" devices aka RAID arrays.
*
* Copyright (C) 2006-2014 Neil Brown <neilb@suse.de>
*
*
* 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 of the License, 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* Author: Neil Brown
* Email: <neil@brown.name>
*
* Specifications for DDF taken from Common RAID DDF Specification Revision 1.2
* (July 28 2006). Reused by permission of SNIA.
*/
#define HAVE_STDINT_H 1
#include "mdadm.h"
#include "mdmon.h"
#include "sha1.h"
#include <values.h>
#include <stddef.h>
/* a non-official T10 name for creation GUIDs */
static char T10[] = "Linux-MD";
/* DDF timestamps are 1980 based, so we need to add
* second-in-decade-of-seventies to convert to linux timestamps.
* 10 years with 2 leap years.
*/
#define DECADE (3600*24*(365*10+2))
unsigned long crc32(
unsigned long crc,
const unsigned char *buf,
unsigned len);
#define DDF_NOTFOUND (~0U)
#define DDF_CONTAINER (DDF_NOTFOUND-1)
/* Default for safe_mode_delay. Same value as for IMSM.
*/
static const int DDF_SAFE_MODE_DELAY = 4000;
/* The DDF metadata handling.
* DDF metadata lives at the end of the device.
* The last 512 byte block provides an 'anchor' which is used to locate
* the rest of the metadata which usually lives immediately behind the anchor.
*
* Note:
* - all multibyte numeric fields are bigendian.
* - all strings are space padded.
*
*/
typedef struct __be16 {
__u16 _v16;
} be16;
#define be16_eq(x, y) ((x)._v16 == (y)._v16)
#define be16_and(x, y) ((x)._v16 & (y)._v16)
#define be16_or(x, y) ((x)._v16 | (y)._v16)
#define be16_clear(x, y) ((x)._v16 &= ~(y)._v16)
#define be16_set(x, y) ((x)._v16 |= (y)._v16)
typedef struct __be32 {
__u32 _v32;
} be32;
#define be32_eq(x, y) ((x)._v32 == (y)._v32)
typedef struct __be64 {
__u64 _v64;
} be64;
#define be64_eq(x, y) ((x)._v64 == (y)._v64)
#define be16_to_cpu(be) __be16_to_cpu((be)._v16)
static inline be16 cpu_to_be16(__u16 x)
{
be16 be = { ._v16 = __cpu_to_be16(x) };
return be;
}
#define be32_to_cpu(be) __be32_to_cpu((be)._v32)
static inline be32 cpu_to_be32(__u32 x)
{
be32 be = { ._v32 = __cpu_to_be32(x) };
return be;
}
#define be64_to_cpu(be) __be64_to_cpu((be)._v64)
static inline be64 cpu_to_be64(__u64 x)
{
be64 be = { ._v64 = __cpu_to_be64(x) };
return be;
}
/* Primary Raid Level (PRL) */
#define DDF_RAID0 0x00
#define DDF_RAID1 0x01
#define DDF_RAID3 0x03
#define DDF_RAID4 0x04
#define DDF_RAID5 0x05
#define DDF_RAID1E 0x11
#define DDF_JBOD 0x0f
#define DDF_CONCAT 0x1f
#define DDF_RAID5E 0x15
#define DDF_RAID5EE 0x25
#define DDF_RAID6 0x06
/* Raid Level Qualifier (RLQ) */
#define DDF_RAID0_SIMPLE 0x00
#define DDF_RAID1_SIMPLE 0x00 /* just 2 devices in this plex */
#define DDF_RAID1_MULTI 0x01 /* exactly 3 devices in this plex */
#define DDF_RAID3_0 0x00 /* parity in first extent */
#define DDF_RAID3_N 0x01 /* parity in last extent */
#define DDF_RAID4_0 0x00 /* parity in first extent */
#define DDF_RAID4_N 0x01 /* parity in last extent */
/* these apply to raid5e and raid5ee as well */
#define DDF_RAID5_0_RESTART 0x00 /* same as 'right asymmetric' - layout 1 */
#define DDF_RAID6_0_RESTART 0x01 /* raid6 different from raid5 here!!! */
#define DDF_RAID5_N_RESTART 0x02 /* same as 'left asymmetric' - layout 0 */
#define DDF_RAID5_N_CONTINUE 0x03 /* same as 'left symmetric' - layout 2 */
#define DDF_RAID1E_ADJACENT 0x00 /* raid10 nearcopies==2 */
#define DDF_RAID1E_OFFSET 0x01 /* raid10 offsetcopies==2 */
/* Secondary RAID Level (SRL) */
#define DDF_2STRIPED 0x00 /* This is weirder than RAID0 !! */
#define DDF_2MIRRORED 0x01
#define DDF_2CONCAT 0x02
#define DDF_2SPANNED 0x03 /* This is also weird - be careful */
/* Magic numbers */
#define DDF_HEADER_MAGIC cpu_to_be32(0xDE11DE11)
#define DDF_CONTROLLER_MAGIC cpu_to_be32(0xAD111111)
#define DDF_PHYS_RECORDS_MAGIC cpu_to_be32(0x22222222)
#define DDF_PHYS_DATA_MAGIC cpu_to_be32(0x33333333)
#define DDF_VIRT_RECORDS_MAGIC cpu_to_be32(0xDDDDDDDD)
#define DDF_VD_CONF_MAGIC cpu_to_be32(0xEEEEEEEE)
#define DDF_SPARE_ASSIGN_MAGIC cpu_to_be32(0x55555555)
#define DDF_VU_CONF_MAGIC cpu_to_be32(0x88888888)
#define DDF_VENDOR_LOG_MAGIC cpu_to_be32(0x01dBEEF0)
#define DDF_BBM_LOG_MAGIC cpu_to_be32(0xABADB10C)
#define DDF_GUID_LEN 24
#define DDF_REVISION_0 "01.00.00"
#define DDF_REVISION_2 "01.02.00"
struct ddf_header {
be32 magic; /* DDF_HEADER_MAGIC */
be32 crc;
char guid[DDF_GUID_LEN];
char revision[8]; /* 01.02.00 */
be32 seq; /* starts at '1' */
be32 timestamp;
__u8 openflag;
__u8 foreignflag;
__u8 enforcegroups;
__u8 pad0; /* 0xff */
__u8 pad1[12]; /* 12 * 0xff */
/* 64 bytes so far */
__u8 header_ext[32]; /* reserved: fill with 0xff */
be64 primary_lba;
be64 secondary_lba;
__u8 type;
__u8 pad2[3]; /* 0xff */
be32 workspace_len; /* sectors for vendor space -
* at least 32768(sectors) */
be64 workspace_lba;
be16 max_pd_entries; /* one of 15, 63, 255, 1023, 4095 */
be16 max_vd_entries; /* 2^(4,6,8,10,12)-1 : i.e. as above */
be16 max_partitions; /* i.e. max num of configuration
record entries per disk */
be16 config_record_len; /* 1 +ROUNDUP(max_primary_element_entries
*12/512) */
be16 max_primary_element_entries; /* 16, 64, 256, 1024, or 4096 */
__u8 pad3[54]; /* 0xff */
/* 192 bytes so far */
be32 controller_section_offset;
be32 controller_section_length;
be32 phys_section_offset;
be32 phys_section_length;
be32 virt_section_offset;
be32 virt_section_length;
be32 config_section_offset;
be32 config_section_length;
be32 data_section_offset;
be32 data_section_length;
be32 bbm_section_offset;
be32 bbm_section_length;
be32 diag_space_offset;
be32 diag_space_length;
be32 vendor_offset;
be32 vendor_length;
/* 256 bytes so far */
__u8 pad4[256]; /* 0xff */
};
/* type field */
#define DDF_HEADER_ANCHOR 0x00
#define DDF_HEADER_PRIMARY 0x01
#define DDF_HEADER_SECONDARY 0x02
/* The content of the 'controller section' - global scope */
struct ddf_controller_data {
be32 magic; /* DDF_CONTROLLER_MAGIC */
be32 crc;
char guid[DDF_GUID_LEN];
struct controller_type {
be16 vendor_id;
be16 device_id;
be16 sub_vendor_id;
be16 sub_device_id;
} type;
char product_id[16];
__u8 pad[8]; /* 0xff */
__u8 vendor_data[448];
};
/* The content of phys_section - global scope */
struct phys_disk {
be32 magic; /* DDF_PHYS_RECORDS_MAGIC */
be32 crc;
be16 used_pdes; /* This is a counter, not a max - the list
* of used entries may not be dense */
be16 max_pdes;
__u8 pad[52];
struct phys_disk_entry {
char guid[DDF_GUID_LEN];
be32 refnum;
be16 type;
be16 state;
be64 config_size; /* DDF structures must be after here */
char path[18]; /* Another horrible structure really
* but is "used for information
* purposes only" */
__u8 pad[6];
} entries[0];
};
/* phys_disk_entry.type is a bitmap - bigendian remember */
#define DDF_Forced_PD_GUID 1
#define DDF_Active_in_VD 2
#define DDF_Global_Spare 4 /* VD_CONF records are ignored */
#define DDF_Spare 8 /* overrides Global_spare */
#define DDF_Foreign 16
#define DDF_Legacy 32 /* no DDF on this device */
#define DDF_Interface_mask 0xf00
#define DDF_Interface_SCSI 0x100
#define DDF_Interface_SAS 0x200
#define DDF_Interface_SATA 0x300
#define DDF_Interface_FC 0x400
/* phys_disk_entry.state is a bigendian bitmap */
#define DDF_Online 1
#define DDF_Failed 2 /* overrides 1,4,8 */
#define DDF_Rebuilding 4
#define DDF_Transition 8
#define DDF_SMART 16
#define DDF_ReadErrors 32
#define DDF_Missing 64
/* The content of the virt_section global scope */
struct virtual_disk {
be32 magic; /* DDF_VIRT_RECORDS_MAGIC */
be32 crc;
be16 populated_vdes;
be16 max_vdes;
__u8 pad[52];
struct virtual_entry {
char guid[DDF_GUID_LEN];
be16 unit;
__u16 pad0; /* 0xffff */
be16 guid_crc;
be16 type;
__u8 state;
__u8 init_state;
__u8 pad1[14];
char name[16];
} entries[0];
};
/* virtual_entry.type is a bitmap - bigendian */
#define DDF_Shared 1
#define DDF_Enforce_Groups 2
#define DDF_Unicode 4
#define DDF_Owner_Valid 8
/* virtual_entry.state is a bigendian bitmap */
#define DDF_state_mask 0x7
#define DDF_state_optimal 0x0
#define DDF_state_degraded 0x1
#define DDF_state_deleted 0x2
#define DDF_state_missing 0x3
#define DDF_state_failed 0x4
#define DDF_state_part_optimal 0x5
#define DDF_state_morphing 0x8
#define DDF_state_inconsistent 0x10
/* virtual_entry.init_state is a bigendian bitmap */
#define DDF_initstate_mask 0x03
#define DDF_init_not 0x00
#define DDF_init_quick 0x01 /* initialisation is progress.
* i.e. 'state_inconsistent' */
#define DDF_init_full 0x02
#define DDF_access_mask 0xc0
#define DDF_access_rw 0x00
#define DDF_access_ro 0x80
#define DDF_access_blocked 0xc0
/* The content of the config_section - local scope
* It has multiple records each config_record_len sectors
* They can be vd_config or spare_assign
*/
struct vd_config {
be32 magic; /* DDF_VD_CONF_MAGIC */
be32 crc;
char guid[DDF_GUID_LEN];
be32 timestamp;
be32 seqnum;
__u8 pad0[24];
be16 prim_elmnt_count;
__u8 chunk_shift; /* 0 == 512, 1==1024 etc */
__u8 prl;
__u8 rlq;
__u8 sec_elmnt_count;
__u8 sec_elmnt_seq;
__u8 srl;
be64 blocks; /* blocks per component could be different
* on different component devices...(only
* for concat I hope) */
be64 array_blocks; /* blocks in array */
__u8 pad1[8];
be32 spare_refs[8]; /* This is used to detect missing spares.
* As we don't have an interface for that
* the values are ignored.
*/
__u8 cache_pol[8];
__u8 bg_rate;
__u8 pad2[3];
__u8 pad3[52];
__u8 pad4[192];
__u8 v0[32]; /* reserved- 0xff */
__u8 v1[32]; /* reserved- 0xff */
__u8 v2[16]; /* reserved- 0xff */
__u8 v3[16]; /* reserved- 0xff */
__u8 vendor[32];
be32 phys_refnum[0]; /* refnum of each disk in sequence */
/*__u64 lba_offset[0]; LBA offset in each phys. Note extents in a
bvd are always the same size */
};
#define LBA_OFFSET(ddf, vd) ((be64 *) &(vd)->phys_refnum[(ddf)->mppe])
/* vd_config.cache_pol[7] is a bitmap */
#define DDF_cache_writeback 1 /* else writethrough */
#define DDF_cache_wadaptive 2 /* only applies if writeback */
#define DDF_cache_readahead 4
#define DDF_cache_radaptive 8 /* only if doing read-ahead */
#define DDF_cache_ifnobatt 16 /* even to write cache if battery is poor */
#define DDF_cache_wallowed 32 /* enable write caching */
#define DDF_cache_rallowed 64 /* enable read caching */
struct spare_assign {
be32 magic; /* DDF_SPARE_ASSIGN_MAGIC */
be32 crc;
be32 timestamp;
__u8 reserved[7];
__u8 type;
be16 populated; /* SAEs used */
be16 max; /* max SAEs */
__u8 pad[8];
struct spare_assign_entry {
char guid[DDF_GUID_LEN];
be16 secondary_element;
__u8 pad[6];
} spare_ents[0];
};
/* spare_assign.type is a bitmap */
#define DDF_spare_dedicated 0x1 /* else global */
#define DDF_spare_revertible 0x2 /* else committable */
#define DDF_spare_active 0x4 /* else not active */
#define DDF_spare_affinity 0x8 /* enclosure affinity */
/* The data_section contents - local scope */
struct disk_data {
be32 magic; /* DDF_PHYS_DATA_MAGIC */
be32 crc;
char guid[DDF_GUID_LEN];
be32 refnum; /* crc of some magic drive data ... */
__u8 forced_ref; /* set when above was not result of magic */
__u8 forced_guid; /* set if guid was forced rather than magic */
__u8 vendor[32];
__u8 pad[442];
};
/* bbm_section content */
struct bad_block_log {
be32 magic;
be32 crc;
be16 entry_count;
be32 spare_count;
__u8 pad[10];
be64 first_spare;
struct mapped_block {
be64 defective_start;
be32 replacement_start;
be16 remap_count;
__u8 pad[2];
} entries[0];
};
/* Struct for internally holding ddf structures */
/* The DDF structure stored on each device is potentially
* quite different, as some data is global and some is local.
* The global data is:
* - ddf header
* - controller_data
* - Physical disk records
* - Virtual disk records
* The local data is:
* - Configuration records
* - Physical Disk data section
* ( and Bad block and vendor which I don't care about yet).
*
* The local data is parsed into separate lists as it is read
* and reconstructed for writing. This means that we only need
* to make config changes once and they are automatically
* propagated to all devices.
* The global (config and disk data) records are each in a list
* of separate data structures. When writing we find the entry
* or entries applicable to the particular device.
*/
struct ddf_super {
struct ddf_header anchor, primary, secondary;
struct ddf_controller_data controller;
struct ddf_header *active;
struct phys_disk *phys;
struct virtual_disk *virt;
char *conf;
int pdsize, vdsize;
unsigned int max_part, mppe, conf_rec_len;
int currentdev;
int updates_pending;
struct vcl {
union {
char space[512];
struct {
struct vcl *next;
unsigned int vcnum; /* index into ->virt */
/* For an array with a secondary level there are
* multiple vd_config structures, all with the same
* guid but with different sec_elmnt_seq.
* One of these structures is in 'conf' below.
* The others are in other_bvds, not in any
* particular order.
*/
struct vd_config **other_bvds;
__u64 *block_sizes; /* NULL if all the same */
};
};
struct vd_config conf;
} *conflist, *currentconf;
struct dl {
union {
char space[512];
struct {
struct dl *next;
int major, minor;
char *devname;
int fd;
unsigned long long size; /* sectors */
be64 primary_lba; /* sectors */
be64 secondary_lba; /* sectors */
be64 workspace_lba; /* sectors */
int pdnum; /* index in ->phys */
struct spare_assign *spare;
void *mdupdate; /* hold metadata update */
/* These fields used by auto-layout */
int raiddisk; /* slot to fill in autolayout */
__u64 esize;
int displayed;
};
};
struct disk_data disk;
struct vcl *vlist[0]; /* max_part in size */
} *dlist, *add_list;
};
#ifndef MDASSEMBLE
static int load_super_ddf_all(struct supertype *st, int fd,
void **sbp, char *devname);
static int get_svd_state(const struct ddf_super *, const struct vcl *);
static int
validate_geometry_ddf_container(struct supertype *st,
int level, int layout, int raiddisks,
int chunk, unsigned long long size,
unsigned long long data_offset,
char *dev, unsigned long long *freesize,
int verbose);
static int validate_geometry_ddf_bvd(struct supertype *st,
int level, int layout, int raiddisks,
int *chunk, unsigned long long size,
unsigned long long data_offset,
char *dev, unsigned long long *freesize,
int verbose);
#endif
static void free_super_ddf(struct supertype *st);
static int all_ff(const char *guid);
static unsigned int get_pd_index_from_refnum(const struct vcl *vc,
be32 refnum, unsigned int nmax,
const struct vd_config **bvd,
unsigned int *idx);
static void getinfo_super_ddf(struct supertype *st, struct mdinfo *info, char *map);
static void uuid_from_ddf_guid(const char *guid, int uuid[4]);
static void uuid_from_super_ddf(struct supertype *st, int uuid[4]);
static void _ddf_array_name(char *name, const struct ddf_super *ddf, int i);
static void getinfo_super_ddf_bvd(struct supertype *st, struct mdinfo *info, char *map);
static int init_super_ddf_bvd(struct supertype *st,
mdu_array_info_t *info,
unsigned long long size,
char *name, char *homehost,
int *uuid, unsigned long long data_offset);
#if DEBUG
static void pr_state(struct ddf_super *ddf, const char *msg)
{
unsigned int i;
dprintf("%s/%s: ", __func__, msg);
for (i = 0; i < be16_to_cpu(ddf->active->max_vd_entries); i++) {
if (all_ff(ddf->virt->entries[i].guid))
continue;
dprintf("%u(s=%02x i=%02x) ", i,
ddf->virt->entries[i].state,
ddf->virt->entries[i].init_state);
}
dprintf("\n");
}
#else
static void pr_state(const struct ddf_super *ddf, const char *msg) {}
#endif
static void _ddf_set_updates_pending(struct ddf_super *ddf, struct vd_config *vc,
const char *func)
{
if (vc) {
vc->timestamp = cpu_to_be32(time(0)-DECADE);
vc->seqnum = cpu_to_be32(be32_to_cpu(vc->seqnum) + 1);
}
if (ddf->updates_pending)
return;
ddf->updates_pending = 1;
ddf->active->seq = cpu_to_be32((be32_to_cpu(ddf->active->seq)+1));
pr_state(ddf, func);
}
#define ddf_set_updates_pending(x,v) _ddf_set_updates_pending((x), (v), __func__)
static be32 calc_crc(void *buf, int len)
{
/* crcs are always at the same place as in the ddf_header */
struct ddf_header *ddf = buf;
be32 oldcrc = ddf->crc;
__u32 newcrc;
ddf->crc = cpu_to_be32(0xffffffff);
newcrc = crc32(0, buf, len);
ddf->crc = oldcrc;
/* The crc is stored (like everything) bigendian, so convert
* here for simplicity
*/
return cpu_to_be32(newcrc);
}
#define DDF_INVALID_LEVEL 0xff
#define DDF_NO_SECONDARY 0xff
static int err_bad_md_layout(const mdu_array_info_t *array)
{
pr_err("RAID%d layout %x with %d disks is unsupported for DDF\n",
array->level, array->layout, array->raid_disks);
return -1;
}
static int layout_md2ddf(const mdu_array_info_t *array,
struct vd_config *conf)
{
be16 prim_elmnt_count = cpu_to_be16(array->raid_disks);
__u8 prl = DDF_INVALID_LEVEL, rlq = 0;
__u8 sec_elmnt_count = 1;
__u8 srl = DDF_NO_SECONDARY;
switch (array->level) {
case LEVEL_LINEAR:
prl = DDF_CONCAT;
break;
case 0:
rlq = DDF_RAID0_SIMPLE;
prl = DDF_RAID0;
break;
case 1:
switch (array->raid_disks) {
case 2:
rlq = DDF_RAID1_SIMPLE;
break;
case 3:
rlq = DDF_RAID1_MULTI;
break;
default:
return err_bad_md_layout(array);
}
prl = DDF_RAID1;
break;
case 4:
if (array->layout != 0)
return err_bad_md_layout(array);
rlq = DDF_RAID4_N;
prl = DDF_RAID4;
break;
case 5:
switch (array->layout) {
case ALGORITHM_LEFT_ASYMMETRIC:
rlq = DDF_RAID5_N_RESTART;
break;
case ALGORITHM_RIGHT_ASYMMETRIC:
rlq = DDF_RAID5_0_RESTART;
break;
case ALGORITHM_LEFT_SYMMETRIC:
rlq = DDF_RAID5_N_CONTINUE;
break;
case ALGORITHM_RIGHT_SYMMETRIC:
/* not mentioned in standard */
default:
return err_bad_md_layout(array);
}
prl = DDF_RAID5;
break;
case 6:
switch (array->layout) {
case ALGORITHM_ROTATING_N_RESTART:
rlq = DDF_RAID5_N_RESTART;
break;
case ALGORITHM_ROTATING_ZERO_RESTART:
rlq = DDF_RAID6_0_RESTART;
break;
case ALGORITHM_ROTATING_N_CONTINUE:
rlq = DDF_RAID5_N_CONTINUE;
break;
default:
return err_bad_md_layout(array);
}
prl = DDF_RAID6;
break;
case 10:
if (array->raid_disks % 2 == 0 && array->layout == 0x102) {
rlq = DDF_RAID1_SIMPLE;
prim_elmnt_count = cpu_to_be16(2);
sec_elmnt_count = array->raid_disks / 2;
srl = DDF_2SPANNED;
prl = DDF_RAID1;
} else if (array->raid_disks % 3 == 0
&& array->layout == 0x103) {
rlq = DDF_RAID1_MULTI;
prim_elmnt_count = cpu_to_be16(3);
sec_elmnt_count = array->raid_disks / 3;
srl = DDF_2SPANNED;
prl = DDF_RAID1;
} else if (array->layout == 0x201) {
prl = DDF_RAID1E;
rlq = DDF_RAID1E_OFFSET;
} else if (array->layout == 0x102) {
prl = DDF_RAID1E;
rlq = DDF_RAID1E_ADJACENT;
} else
return err_bad_md_layout(array);
break;
default:
return err_bad_md_layout(array);
}
conf->prl = prl;
conf->prim_elmnt_count = prim_elmnt_count;
conf->rlq = rlq;
conf->srl = srl;
conf->sec_elmnt_count = sec_elmnt_count;
return 0;
}
static int err_bad_ddf_layout(const struct vd_config *conf)
{
pr_err("DDF RAID %u qualifier %u with %u disks is unsupported\n",
conf->prl, conf->rlq, be16_to_cpu(conf->prim_elmnt_count));
return -1;
}
static int layout_ddf2md(const struct vd_config *conf,
mdu_array_info_t *array)
{
int level = LEVEL_UNSUPPORTED;
int layout = 0;
int raiddisks = be16_to_cpu(conf->prim_elmnt_count);
if (conf->sec_elmnt_count > 1) {
/* see also check_secondary() */
if (conf->prl != DDF_RAID1 ||
(conf->srl != DDF_2STRIPED && conf->srl != DDF_2SPANNED)) {
pr_err("Unsupported secondary RAID level %u/%u\n",
conf->prl, conf->srl);
return -1;
}
if (raiddisks == 2 && conf->rlq == DDF_RAID1_SIMPLE)
layout = 0x102;
else if (raiddisks == 3 && conf->rlq == DDF_RAID1_MULTI)
layout = 0x103;
else
return err_bad_ddf_layout(conf);
raiddisks *= conf->sec_elmnt_count;
level = 10;
goto good;
}
switch (conf->prl) {
case DDF_CONCAT:
level = LEVEL_LINEAR;
break;
case DDF_RAID0:
if (conf->rlq != DDF_RAID0_SIMPLE)
return err_bad_ddf_layout(conf);
level = 0;
break;
case DDF_RAID1:
if (!((conf->rlq == DDF_RAID1_SIMPLE && raiddisks == 2) ||
(conf->rlq == DDF_RAID1_MULTI && raiddisks == 3)))
return err_bad_ddf_layout(conf);
level = 1;
break;
case DDF_RAID1E:
if (conf->rlq == DDF_RAID1E_ADJACENT)
layout = 0x102;
else if (conf->rlq == DDF_RAID1E_OFFSET)
layout = 0x201;
else
return err_bad_ddf_layout(conf);
level = 10;
break;
case DDF_RAID4:
if (conf->rlq != DDF_RAID4_N)
return err_bad_ddf_layout(conf);
level = 4;
break;
case DDF_RAID5:
switch (conf->rlq) {
case DDF_RAID5_N_RESTART:
layout = ALGORITHM_LEFT_ASYMMETRIC;
break;
case DDF_RAID5_0_RESTART:
layout = ALGORITHM_RIGHT_ASYMMETRIC;
break;
case DDF_RAID5_N_CONTINUE:
layout = ALGORITHM_LEFT_SYMMETRIC;
break;
default:
return err_bad_ddf_layout(conf);
}
level = 5;
break;
case DDF_RAID6:
switch (conf->rlq) {
case DDF_RAID5_N_RESTART:
layout = ALGORITHM_ROTATING_N_RESTART;
break;
case DDF_RAID6_0_RESTART:
layout = ALGORITHM_ROTATING_ZERO_RESTART;
break;
case DDF_RAID5_N_CONTINUE:
layout = ALGORITHM_ROTATING_N_CONTINUE;
break;
default:
return err_bad_ddf_layout(conf);
}
level = 6;
break;
default:
return err_bad_ddf_layout(conf);
};
good:
array->level = level;
array->layout = layout;
array->raid_disks = raiddisks;
return 0;
}
static int load_ddf_header(int fd, unsigned long long lba,
unsigned long long size,
int type,
struct ddf_header *hdr, struct ddf_header *anchor)
{
/* read a ddf header (primary or secondary) from fd/lba
* and check that it is consistent with anchor
* Need to check:
* magic, crc, guid, rev, and LBA's header_type, and
* everything after header_type must be the same
*/
if (lba >= size-1)
return 0;
if (lseek64(fd, lba<<9, 0) < 0)
return 0;
if (read(fd, hdr, 512) != 512)
return 0;
if (!be32_eq(hdr->magic, DDF_HEADER_MAGIC)) {
pr_err("%s: bad header magic\n", __func__);
return 0;
}
if (!be32_eq(calc_crc(hdr, 512), hdr->crc)) {
pr_err("%s: bad CRC\n", __func__);
return 0;
}
if (memcmp(anchor->guid, hdr->guid, DDF_GUID_LEN) != 0 ||
memcmp(anchor->revision, hdr->revision, 8) != 0 ||
!be64_eq(anchor->primary_lba, hdr->primary_lba) ||
!be64_eq(anchor->secondary_lba, hdr->secondary_lba) ||
hdr->type != type ||
memcmp(anchor->pad2, hdr->pad2, 512 -
offsetof(struct ddf_header, pad2)) != 0) {
pr_err("%s: header mismatch\n", __func__);
return 0;
}
/* Looks good enough to me... */
return 1;
}
static void *load_section(int fd, struct ddf_super *super, void *buf,
be32 offset_be, be32 len_be, int check)
{
unsigned long long offset = be32_to_cpu(offset_be);
unsigned long long len = be32_to_cpu(len_be);
int dofree = (buf == NULL);
if (check)
if (len != 2 && len != 8 && len != 32
&& len != 128 && len != 512)
return NULL;
if (len > 1024)
return NULL;
if (!buf && posix_memalign(&buf, 512, len<<9) != 0)
buf = NULL;
if (!buf)
return NULL;
if (super->active->type == 1)
offset += be64_to_cpu(super->active->primary_lba);
else
offset += be64_to_cpu(super->active->secondary_lba);
if ((unsigned long long)lseek64(fd, offset<<9, 0) != (offset<<9)) {
if (dofree)
free(buf);
return NULL;
}
if ((unsigned long long)read(fd, buf, len<<9) != (len<<9)) {
if (dofree)
free(buf);
return NULL;
}
return buf;
}
static int load_ddf_headers(int fd, struct ddf_super *super, char *devname)
{
unsigned long long dsize;
get_dev_size(fd, NULL, &dsize);
if (lseek64(fd, dsize-512, 0) < 0) {
if (devname)
pr_err("Cannot seek to anchor block on %s: %s\n",
devname, strerror(errno));
return 1;
}
if (read(fd, &super->anchor, 512) != 512) {
if (devname)
pr_err("Cannot read anchor block on %s: %s\n",
devname, strerror(errno));
return 1;
}
if (!be32_eq(super->anchor.magic, DDF_HEADER_MAGIC)) {
if (devname)
pr_err("no DDF anchor found on %s\n",
devname);
return 2;
}
if (!be32_eq(calc_crc(&super->anchor, 512), super->anchor.crc)) {
if (devname)
pr_err("bad CRC on anchor on %s\n",
devname);
return 2;
}
if (memcmp(super->anchor.revision, DDF_REVISION_0, 8) != 0 &&
memcmp(super->anchor.revision, DDF_REVISION_2, 8) != 0) {
if (devname)
pr_err("can only support super revision"
" %.8s and earlier, not %.8s on %s\n",
DDF_REVISION_2, super->anchor.revision,devname);
return 2;
}
super->active = NULL;
if (load_ddf_header(fd, be64_to_cpu(super->anchor.primary_lba),
dsize >> 9, 1,
&super->primary, &super->anchor) == 0) {
if (devname)
pr_err("Failed to load primary DDF header "
"on %s\n", devname);
} else
super->active = &super->primary;
if (load_ddf_header(fd, be64_to_cpu(super->anchor.secondary_lba),
dsize >> 9, 2,
&super->secondary, &super->anchor)) {
if (super->active == NULL
|| (be32_to_cpu(super->primary.seq)
< be32_to_cpu(super->secondary.seq) &&
!super->secondary.openflag)
|| (be32_to_cpu(super->primary.seq)
== be32_to_cpu(super->secondary.seq) &&
super->primary.openflag && !super->secondary.openflag)
)
super->active = &super->secondary;
} else if (devname &&
be64_to_cpu(super->anchor.secondary_lba) != ~(__u64)0)
pr_err("Failed to load secondary DDF header on %s\n",
devname);
if (super->active == NULL)
return 2;
return 0;
}
static int load_ddf_global(int fd, struct ddf_super *super, char *devname)
{
void *ok;
ok = load_section(fd, super, &super->controller,
super->active->controller_section_offset,
super->active->controller_section_length,
0);
super->phys = load_section(fd, super, NULL,
super->active->phys_section_offset,
super->active->phys_section_length,
1);
super->pdsize = be32_to_cpu(super->active->phys_section_length) * 512;
super->virt = load_section(fd, super, NULL,
super->active->virt_section_offset,
super->active->virt_section_length,
1);
super->vdsize = be32_to_cpu(super->active->virt_section_length) * 512;
if (!ok ||
!super->phys ||
!super->virt) {
free(super->phys);
free(super->virt);
super->phys = NULL;
super->virt = NULL;
return 2;
}
super->conflist = NULL;
super->dlist = NULL;
super->max_part = be16_to_cpu(super->active->max_partitions);
super->mppe = be16_to_cpu(super->active->max_primary_element_entries);
super->conf_rec_len = be16_to_cpu(super->active->config_record_len);
return 0;
}
#define DDF_UNUSED_BVD 0xff
static int alloc_other_bvds(const struct ddf_super *ddf, struct vcl *vcl)
{
unsigned int n_vds = vcl->conf.sec_elmnt_count - 1;
unsigned int i, vdsize;
void *p;
if (n_vds == 0) {
vcl->other_bvds = NULL;