-/* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
- * vim:expandtab:shiftwidth=8:tabstop=8:
- *
+/*
* GPL HEADER START
*
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
/*
* Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved.
* Use is subject to license terms.
+ *
+ * Copyright (c) 2011, 2012, Whamcloud, Inc.
*/
/*
* This file is part of Lustre, http://www.lustre.org/
/** \defgroup fid fid
*
* @{
+ *
+ * http://wiki.lustre.org/index.php/Architecture_-_Interoperability_fids_zfs
+ * describes the FID namespace and interoperability requirements for FIDs.
+ * The important parts of that document are included here for reference.
+ *
+ * FID
+ * File IDentifier generated by client from range allocated by the SEQuence
+ * service and stored in struct lu_fid. The FID is composed of three parts:
+ * SEQuence, ObjectID, and VERsion. The SEQ component is a filesystem
+ * unique 64-bit integer, and only one client is ever assigned any SEQ value.
+ * The first 0x400 FID_SEQ_NORMAL [2^33, 2^33 + 0x400] values are reserved
+ * for system use. The OID component is a 32-bit value generated by the
+ * client on a per-SEQ basis to allow creating many unique FIDs without
+ * communication with the server. The VER component is a 32-bit value that
+ * distinguishes between different FID instantiations, such as snapshots or
+ * separate subtrees within the filesystem. FIDs with the same VER field
+ * are considered part of the same namespace.
+ *
+ * OLD filesystems are those upgraded from Lustre 1.x that predate FIDs, and
+ * MDTs use 32-bit ldiskfs internal inode/generation numbers (IGIFs), while
+ * OSTs use 64-bit Lustre object IDs and generation numbers.
+ *
+ * NEW filesystems are those formatted since the introduction of FIDs.
+ *
+ * IGIF
+ * Inode and Generation In FID, a surrogate FID used to globally identify
+ * an existing object on OLD formatted MDT file system. This would only be
+ * used on MDT0 in a DNE filesystem, because there cannot be more than one
+ * MDT in an OLD formatted filesystem. Belongs to sequence in [12, 2^32 - 1]
+ * range, where inode number is stored in SEQ, and inode generation is in OID.
+ * NOTE: This assumes no more than 2^32-1 inodes exist in the MDT filesystem,
+ * which is the maximum possible for an ldiskfs backend. It also assumes
+ * that the reserved ext3/ext4/ldiskfs inode numbers [0-11] are never visible
+ * to clients, which has always been true.
+ *
+ * IDIF
+ * object ID In FID, a surrogate FID used to globally identify an existing
+ * OST object on OLD formatted OST file system. Belongs to a sequence in
+ * [2^32, 2^33 - 1]. Sequence number is calculated as:
+ *
+ * 1 << 32 | (ost_index << 16) | ((objid >> 32) & 0xffff)
+ *
+ * that is, SEQ consists of 16-bit OST index, and higher 16 bits of object
+ * ID. The generation of unique SEQ values per OST allows the IDIF FIDs to
+ * be identified in the FLD correctly. The OID field is calculated as:
+ *
+ * objid & 0xffffffff
+ *
+ * that is, it consists of lower 32 bits of object ID. For objects within
+ * the IDIF range, object ID extraction will be:
+ *
+ * o_id = (fid->f_seq & 0x7fff) << 16 | fid->f_oid;
+ * o_seq = 0; // formerly group number
+ *
+ * NOTE: This assumes that no more than 2^48-1 objects have ever been created
+ * on any OST, and that no more than 65535 OSTs are in use. Both are very
+ * reasonable assumptions, i.e. an IDIF can uniquely map all objects assuming
+ * a maximum creation rate of 1M objects per second for a maximum of 9 years,
+ * or combinations thereof.
+ *
+ * OST_MDT0
+ * Surrogate FID used to identify an existing object on OLD formatted OST
+ * filesystem. Belongs to the reserved SEQuence 0, and is used prior to
+ * the introduction of FID-on-OST, at which point IDIF will be used to
+ * identify objects as residing on a specific OST.
+ *
+ * LLOG
+ * For Lustre Log objects the object sequence 1 is used. This is compatible
+ * with both OLD and NEW namespaces, as this SEQ number is in the
+ * ext3/ldiskfs reserved inode range and does not conflict with IGIF
+ * sequence numbers.
+ *
+ * ECHO
+ * For testing OST IO performance the object sequence 2 is used. This is
+ * compatible with both OLD and NEW namespaces, as this SEQ number is in
+ * the ext3/ldiskfs reserved inode range and does not conflict with IGIF
+ * sequence numbers.
+ *
+ * OST_MDT1 .. OST_MAX
+ * For testing with multiple MDTs the object sequence 3 through 9 is used,
+ * allowing direct mapping of MDTs 1 through 7 respectively, for a total
+ * of 8 MDTs including OST_MDT0. This matches the legacy CMD project "group"
+ * mappings. However, this SEQ range is only for testing prior to any
+ * production DNE release, as the objects in this range conflict across all
+ * OSTs, as the OST index is not part of the FID. For production DNE usage,
+ * OST objects created by MDT1+ will use FID_SEQ_NORMAL FIDs.
+ *
+ * DLM OST objid to IDIF mapping
+ * For compatibility with existing OLD OST network protocol structures, the
+ * FID must map onto the o_id and o_seq in a manner that ensures existing
+ * objects are identified consistently for IO, as well as onto the LDLM
+ * namespace to ensure IDIFs there is only a single resource name for any
+ * object in the DLM. The OLD OST object DLM resource mapping is:
+ *
+ * resource[] = {o_id, o_seq, 0, 0}; // o_seq == 0 for production releases
+ *
+ * The NEW OST object DLM resource mapping is the same for both MDT and OST:
+ *
+ * resource[] = {SEQ, OID, VER, HASH};
+ *
+ * NOTE: for mapping IDIF values to DLM resource names the o_id may be
+ * larger than the 2^33 reserved sequence numbers for IDIF, so it is possible
+ * for the o_id numbers to overlap FID SEQ numbers in the resource. However,
+ * in all production releases the OLD o_seq field is always zero, and all
+ * valid FID OID values are non-zero, so the lock resources will not collide.
+ * Even so, the MDT and OST resources are also in different LDLM namespaces.
*/
-/*
- * struct lu_fid
- */
#include <libcfs/libcfs.h>
#include <lustre/lustre_idl.h>
#include <lustre_req_layout.h>
LUSTRE_SEQ_SUPER_WIDTH = ((1ULL << 30ULL) * LUSTRE_SEQ_META_WIDTH)
};
+enum {
+ /** 2^6 FIDs for OI containers */
+ OSD_OI_FID_OID_BITS = 6,
+ /** reserve enough FIDs in case we want more in the future */
+ OSD_OI_FID_OID_BITS_MAX = 10,
+};
+
/** special OID for local objects */
enum local_oid {
- /** \see osd_oi_index_create */
- OSD_OI_FID_16_OID = 2UL,
/** \see fld_mod_init */
FLD_INDEX_OID = 3UL,
/** \see fid_mod_init */
MDD_ORPHAN_OID = 7UL,
MDD_LOV_OBJ_OID = 8UL,
MDD_CAPA_KEYS_OID = 9UL,
- MDD_OBJECTS_OID = 10UL,
/** \see mdt_mod_init */
MDT_LAST_RECV_OID = 11UL,
- /** \see osd_mod_init */
- OSD_REM_OBJ_DIR_OID = 12UL,
+ OSD_FS_ROOT_OID = 13UL,
+ ACCT_USER_OID = 15UL,
+ ACCT_GROUP_OID = 16UL,
+ LFSCK_BOOKMARK_OID = 17UL,
+ OTABLE_IT_OID = 18UL,
+ OFD_LAST_RECV_OID = 19UL,
+ OFD_GROUP0_LAST_OID = 20UL,
+ OFD_GROUP4K_LAST_OID = 20UL+4096,
+ OFD_LAST_GROUP_OID = 4117UL,
+ LLOG_CATALOGS_OID = 4118UL,
+ MGS_CONFIGS_OID = 4119UL,
+ OFD_HEALTH_CHECK_OID = 4120UL,
};
static inline void lu_local_obj_fid(struct lu_fid *fid, __u32 oid)
fid->f_ver = 0;
}
+static inline void lu_local_name_obj_fid(struct lu_fid *fid, __u32 oid)
+{
+ fid->f_seq = FID_SEQ_LOCAL_NAME;
+ fid->f_oid = oid;
+ fid->f_ver = 0;
+}
+
+static inline int fid_is_otable_it(const struct lu_fid *fid)
+{
+ return unlikely(fid_seq(fid) == FID_SEQ_LOCAL_FILE &&
+ fid_oid(fid) == OTABLE_IT_OID);
+}
+
+static inline int fid_is_acct(const struct lu_fid *fid)
+{
+ return fid_seq(fid) == FID_SEQ_LOCAL_FILE &&
+ (fid_oid(fid) == ACCT_USER_OID ||
+ fid_oid(fid) == ACCT_GROUP_OID);
+}
+
+static inline int fid_is_quota(const struct lu_fid *fid)
+{
+ return fid_seq(fid) == FID_SEQ_QUOTA ||
+ fid_seq(fid) == FID_SEQ_QUOTA_GLB;
+}
+
enum lu_mgr_type {
LUSTRE_SEQ_SERVER,
LUSTRE_SEQ_CONTROLLER
struct lu_client_seq {
/* Sequence-controller export. */
struct obd_export *lcs_exp;
- cfs_semaphore_t lcs_sem;
+ cfs_mutex_t lcs_mutex;
/*
* Range of allowed for allocation sequeces. When using lu_client_seq on
/* Seq-server for direct talking */
struct lu_server_seq *lcs_srv;
+
+ /* wait queue for fid allocation and update indicator */
+ cfs_waitq_t lcs_waitq;
+ int lcs_update;
};
/* server sequence manager interface */
/* Client interafce to request controller */
struct lu_client_seq *lss_cli;
- /* Semaphore for protecting allocation */
- cfs_semaphore_t lss_sem;
+ /* Mutex for protecting allocation */
+ cfs_mutex_t lss_mutex;
/*
* Service uuid, passed from MDT + seq name to form unique seq name to
*/
__u64 lss_set_width;
- /* transaction no of seq update write operation */
- __u64 lss_set_transno;
+ /* sync is needed for update operation */
+ __u32 lss_need_sync;
/**
* Pointer to site object, required to access site fld.
*/
void seq_client_flush(struct lu_client_seq *seq);
-int seq_client_alloc_fid(struct lu_client_seq *seq,
+int seq_client_alloc_fid(const struct lu_env *env, struct lu_client_seq *seq,
struct lu_fid *fid);
+int seq_client_get_seq(const struct lu_env *env, struct lu_client_seq *seq,
+ seqno_t *seqnr);
/* Fids common stuff */
int fid_is_local(const struct lu_env *env,
struct ldlm_namespace;
-enum {
- LUSTRE_RES_ID_SEQ_OFF = 0,
- LUSTRE_RES_ID_OID_OFF = 1,
- LUSTRE_RES_ID_VER_OFF = 2,
- LUSTRE_RES_ID_HSH_OFF = 3
-};
-
/*
- * Build (DLM) resource name from fid.
+ * Build (DLM) resource name from FID.
+ *
+ * NOTE: until Lustre 1.8.7/2.1.1 the fid_ver() was packed into name[2],
+ * but was moved into name[1] along with the OID to avoid consuming the
+ * renaming name[2,3] fields that need to be used for the quota identifier.
*/
static inline struct ldlm_res_id *
fid_build_reg_res_name(const struct lu_fid *f,
{
memset(name, 0, sizeof *name);
name->name[LUSTRE_RES_ID_SEQ_OFF] = fid_seq(f);
- name->name[LUSTRE_RES_ID_OID_OFF] = fid_oid(f);
- name->name[LUSTRE_RES_ID_VER_OFF] = fid_ver(f);
+ name->name[LUSTRE_RES_ID_VER_OID_OFF] = fid_ver_oid(f);
return name;
}
/*
+ * Build (DLM) resource identifier from global quota FID and quota ID.
+ */
+static inline struct ldlm_res_id *
+fid_build_quota_resid(const struct lu_fid *glb_fid, union lquota_id *qid,
+ struct ldlm_res_id *res)
+{
+ fid_build_reg_res_name(glb_fid, res);
+ res->name[LUSTRE_RES_ID_QUOTA_SEQ_OFF] = fid_seq(&qid->qid_fid);
+ res->name[LUSTRE_RES_ID_QUOTA_VER_OID_OFF] = fid_ver_oid(&qid->qid_fid);
+ return res;
+}
+
+/*
+ * Extract global FID and quota ID from resource name
+ */
+static inline void fid_extract_quota_resid(struct ldlm_res_id *res,
+ struct lu_fid *glb_fid,
+ union lquota_id *qid)
+{
+ glb_fid->f_seq = res->name[LUSTRE_RES_ID_SEQ_OFF];
+ glb_fid->f_oid = (__u32)res->name[LUSTRE_RES_ID_VER_OID_OFF];
+ glb_fid->f_ver = (__u32)(res->name[LUSTRE_RES_ID_VER_OID_OFF] >> 32);
+
+ qid->qid_fid.f_seq = res->name[LUSTRE_RES_ID_QUOTA_SEQ_OFF];
+ qid->qid_fid.f_oid = (__u32)res->name[LUSTRE_RES_ID_QUOTA_VER_OID_OFF];
+ qid->qid_fid.f_ver =
+ (__u32)(res->name[LUSTRE_RES_ID_QUOTA_VER_OID_OFF] >> 32);
+}
+
+/*
* Return true if resource is for object identified by fid.
*/
static inline int fid_res_name_eq(const struct lu_fid *f,
const struct ldlm_res_id *name)
{
- return
- name->name[LUSTRE_RES_ID_SEQ_OFF] == fid_seq(f) &&
- name->name[LUSTRE_RES_ID_OID_OFF] == fid_oid(f) &&
- name->name[LUSTRE_RES_ID_VER_OFF] == fid_ver(f);
+ return name->name[LUSTRE_RES_ID_SEQ_OFF] == fid_seq(f) &&
+ name->name[LUSTRE_RES_ID_VER_OID_OFF] == fid_ver_oid(f);
}
/**
- * Flatten 128-bit FID values into a 64-bit value for
- * use as an inode number. For non-IGIF FIDs this
- * starts just over 2^32, and continues without conflict
- * until 2^64, at which point we wrap the high 32 bits
- * of the SEQ into the range where there may not be many
- * OID values in use, to minimize the risk of conflict.
- *
- * The time between re-used inode numbers is very long -
- * 2^32 SEQ numbers, or about 2^32 client mounts. */
+ * Flatten 128-bit FID values into a 64-bit value for use as an inode number.
+ * For non-IGIF FIDs this starts just over 2^32, and continues without
+ * conflict until 2^64, at which point we wrap the high 24 bits of the SEQ
+ * into the range where there may not be many OID values in use, to minimize
+ * the risk of conflict.
+ *
+ * Suppose LUSTRE_SEQ_MAX_WIDTH less than (1 << 24) which is currently true,
+ * the time between re-used inode numbers is very long - 2^40 SEQ numbers,
+ * or about 2^40 client mounts, if clients create less than 2^24 files/mount.
+ */
static inline __u64 fid_flatten(const struct lu_fid *fid)
{
__u64 ino;
seq = fid_seq(fid);
- ino = (seq << 24) + ((seq >> (64-8)) & 0xffffff0000ULL) + fid_oid(fid);
+ ino = (seq << 24) + ((seq >> 24) & 0xffffff0000ULL) + fid_oid(fid);
RETURN(ino ? ino : fid_oid(fid));
}
+static inline __u32 fid_hash(const struct lu_fid *f, int bits)
+{
+ /* all objects with same id and different versions will belong to same
+ * collisions list. */
+ return cfs_hash_long(fid_flatten(f), bits);
+}
+
/**
* map fid to 32 bit value for ino on 32bit systems. */
static inline __u32 fid_flatten32(const struct lu_fid *fid)
seq = fid_seq(fid) - FID_SEQ_START;
- /*
- map the high bits of the OID into higher bits of the inode number so that
- inodes generated at about the same time have a reduced chance of collisions.
- This will give a period of 1024 clients and 128 k = 128M inodes without collisions.
- */
-
+ /* Map the high bits of the OID into higher bits of the inode number so
+ * that inodes generated at about the same time have a reduced chance
+ * of collisions. This will give a period of 2^12 = 1024 unique clients
+ * (from SEQ) and up to min(LUSTRE_SEQ_MAX_WIDTH, 2^20) = 128k objects
+ * (from OID), or up to 128M inodes without collisions for new files. */
ino = ((seq & 0x000fffffULL) << 12) + ((seq >> 8) & 0xfffff000) +
(seq >> (64 - (40-8)) & 0xffffff00) +
- (fid_oid(fid) & 0xff000fff) + ((fid_oid(fid) & 0x00fff000) << 16);
+ (fid_oid(fid) & 0xff000fff) + ((fid_oid(fid) & 0x00fff000) << 8);
RETURN(ino ? ino : fid_oid(fid));
}