- using TASK_INTERRUPTIBLE in OBD_SLEEP_ON at Andreas' suggestion.

[fs/lustre-release.git] / lustre / include / linux / obd_support.h

/* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
 * vim:expandtab:shiftwidth=8:tabstop=8:
 *
 *  Copyright (C) 2001, 2002 Cluster File Systems, Inc.
 *
 *   This file is part of Lustre, http://www.lustre.org.
 *
 *   Lustre is free software; you can redistribute it and/or
 *   modify it under the terms of version 2 of the GNU General Public
 *   License as published by the Free Software Foundation.
 *
 *   Lustre 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 Lustre; if not, write to the Free Software
 *   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 *
 */

#ifndef _OBD_SUPPORT
#define _OBD_SUPPORT

#ifdef __KERNEL__
#include <linux/config.h>
#include <linux/autoconf.h>
#include <linux/slab.h>
#include <linux/highmem.h>
#include <linux/buffer_head.h>
#endif
#include <libcfs/kp30.h>
#include <linux/lustre_compat25.h>

/* global variables */
extern int obd_memmax;
extern atomic_t obd_memory;

extern unsigned int obd_fail_loc;
extern unsigned int obd_timeout;
extern unsigned int ldlm_timeout;
extern char obd_lustre_upcall[128];
extern unsigned int obd_sync_filter;
extern unsigned int obd_dump_on_timeout;
extern wait_queue_head_t obd_race_waitq;

#define OBD_FAIL_MDS                     0x100
#define OBD_FAIL_MDS_HANDLE_UNPACK       0x101
#define OBD_FAIL_MDS_GETATTR_NET         0x102
#define OBD_FAIL_MDS_GETATTR_PACK        0x103
#define OBD_FAIL_MDS_READPAGE_NET        0x104
#define OBD_FAIL_MDS_READPAGE_PACK       0x105
#define OBD_FAIL_MDS_SENDPAGE            0x106
#define OBD_FAIL_MDS_REINT_NET           0x107
#define OBD_FAIL_MDS_REINT_UNPACK        0x108
#define OBD_FAIL_MDS_REINT_SETATTR       0x109
#define OBD_FAIL_MDS_REINT_SETATTR_WRITE 0x10a
#define OBD_FAIL_MDS_REINT_CREATE        0x10b
#define OBD_FAIL_MDS_REINT_CREATE_WRITE  0x10c
#define OBD_FAIL_MDS_REINT_UNLINK        0x10d
#define OBD_FAIL_MDS_REINT_UNLINK_WRITE  0x10e
#define OBD_FAIL_MDS_REINT_LINK          0x10f
#define OBD_FAIL_MDS_REINT_LINK_WRITE    0x110
#define OBD_FAIL_MDS_REINT_RENAME        0x111
#define OBD_FAIL_MDS_REINT_RENAME_WRITE  0x112
#define OBD_FAIL_MDS_OPEN_NET            0x113
#define OBD_FAIL_MDS_OPEN_PACK           0x114
#define OBD_FAIL_MDS_CLOSE_NET           0x115
#define OBD_FAIL_MDS_CLOSE_PACK          0x116
#define OBD_FAIL_MDS_CONNECT_NET         0x117
#define OBD_FAIL_MDS_CONNECT_PACK        0x118
#define OBD_FAIL_MDS_REINT_NET_REP       0x119
#define OBD_FAIL_MDS_DISCONNECT_NET      0x11a
#define OBD_FAIL_MDS_GETSTATUS_NET       0x11b
#define OBD_FAIL_MDS_GETSTATUS_PACK      0x11c
#define OBD_FAIL_MDS_STATFS_PACK         0x11d
#define OBD_FAIL_MDS_STATFS_NET          0x11e
#define OBD_FAIL_MDS_GETATTR_LOCK_NET    0x11f
#define OBD_FAIL_MDS_PIN_NET             0x120
#define OBD_FAIL_MDS_UNPIN_NET           0x121
#define OBD_FAIL_MDS_ALL_REPLY_NET       0x122
#define OBD_FAIL_MDS_ALL_REQUEST_NET     0x123
#define OBD_FAIL_MDS_SYNC_NET            0x124
#define OBD_FAIL_MDS_SYNC_PACK           0x125
#define OBD_FAIL_MDS_DONE_WRITING_NET    0x126
#define OBD_FAIL_MDS_DONE_WRITING_PACK   0x127
#define OBD_FAIL_MDS_ALLOC_OBDO          0x128
#define OBD_FAIL_MDS_PAUSE_OPEN          0x129
#define OBD_FAIL_MDS_STATFS_LCW_SLEEP    0x12a
#define OBD_FAIL_MDS_OPEN_CREATE         0x12b

#define OBD_FAIL_OST                     0x200
#define OBD_FAIL_OST_CONNECT_NET         0x201
#define OBD_FAIL_OST_DISCONNECT_NET      0x202
#define OBD_FAIL_OST_GET_INFO_NET        0x203
#define OBD_FAIL_OST_CREATE_NET          0x204
#define OBD_FAIL_OST_DESTROY_NET         0x205
#define OBD_FAIL_OST_GETATTR_NET         0x206
#define OBD_FAIL_OST_SETATTR_NET         0x207
#define OBD_FAIL_OST_OPEN_NET            0x208
#define OBD_FAIL_OST_CLOSE_NET           0x209
#define OBD_FAIL_OST_BRW_NET             0x20a
#define OBD_FAIL_OST_PUNCH_NET           0x20b
#define OBD_FAIL_OST_STATFS_NET          0x20c
#define OBD_FAIL_OST_HANDLE_UNPACK       0x20d
#define OBD_FAIL_OST_BRW_WRITE_BULK      0x20e
#define OBD_FAIL_OST_BRW_READ_BULK       0x20f
#define OBD_FAIL_OST_SYNC_NET            0x210
#define OBD_FAIL_OST_ALL_REPLY_NET       0x211
#define OBD_FAIL_OST_ALL_REQUESTS_NET    0x212
#define OBD_FAIL_OST_LDLM_REPLY_NET      0x213
#define OBD_FAIL_OST_BRW_PAUSE_BULK      0x214
#define OBD_FAIL_OST_ENOSPC              0x215
#define OBD_FAIL_OST_EROFS               0x216


#define OBD_FAIL_LDLM                    0x300
#define OBD_FAIL_LDLM_NAMESPACE_NEW      0x301
#define OBD_FAIL_LDLM_ENQUEUE            0x302
#define OBD_FAIL_LDLM_CONVERT            0x303
#define OBD_FAIL_LDLM_CANCEL             0x304
#define OBD_FAIL_LDLM_BL_CALLBACK        0x305
#define OBD_FAIL_LDLM_CP_CALLBACK        0x306
#define OBD_FAIL_LDLM_GL_CALLBACK        0x307
#define OBD_FAIL_LDLM_ENQUEUE_EXTENT_ERR 0x308
#define OBD_FAIL_LDLM_ENQUEUE_INTENT_ERR 0x309
#define OBD_FAIL_LDLM_CREATE_RESOURCE    0x30a
#define OBD_FAIL_LDLM_ENQUEUE_BLOCKED    0x30b
#define OBD_FAIL_LDLM_REPLY              0x30c


#define OBD_FAIL_OSC                     0x400
#define OBD_FAIL_OSC_BRW_READ_BULK       0x401
#define OBD_FAIL_OSC_BRW_WRITE_BULK      0x402
#define OBD_FAIL_OSC_LOCK_BL_AST         0x403
#define OBD_FAIL_OSC_LOCK_CP_AST         0x404
#define OBD_FAIL_OSC_MATCH               0x405

#define OBD_FAIL_PTLRPC                  0x500
#define OBD_FAIL_PTLRPC_ACK              0x501
#define OBD_FAIL_PTLRPC_RQBD             0x502
#define OBD_FAIL_PTLRPC_BULK_GET_NET     0x503
#define OBD_FAIL_PTLRPC_BULK_PUT_NET     0x504

#define OBD_FAIL_OBD_PING_NET            0x600
#define OBD_FAIL_OBD_LOG_CANCEL_NET      0x601
#define OBD_FAIL_OBD_LOGD_NET            0x602

#define OBD_FAIL_TGT_REPLY_NET           0x700
#define OBD_FAIL_TGT_CONN_RACE           0x701

#define OBD_FAIL_SVCSEC_ACCEPT_BEG       0x750
#define OBD_FAIL_SVCSEC_ACCEPT_END       0x751
#define OBD_FAIL_SVCSEC_WRAP_BEG         0x752
#define OBD_FAIL_SVCSEC_WRAP_END         0x753
#define OBD_FAIL_SVCGSS_ERR_NOTIFY       0x760
#define OBD_FAIL_SVCGSS_INIT_REQ         0x780
#define OBD_FAIL_SVCGSS_INIT_REP         0x781

#define OBD_FAIL_MDC_REVALIDATE_PAUSE    0x800

/* preparation for a more advanced failure testbed (not functional yet) */
#define OBD_FAIL_MASK_SYS    0x0000FF00
#define OBD_FAIL_MASK_LOC    (0x000000FF | OBD_FAIL_MASK_SYS)
#define OBD_FAIL_ONCE        0x80000000
#define OBD_FAILED           0x40000000
#define OBD_FAIL_MDS_ALL_NET 0x01000000
#define OBD_FAIL_OST_ALL_NET 0x02000000

#define OBD_FAIL_CHECK(id)   (((obd_fail_loc & OBD_FAIL_MASK_LOC) ==           \
                              ((id) & OBD_FAIL_MASK_LOC)) &&                   \
                              ((obd_fail_loc & (OBD_FAILED | OBD_FAIL_ONCE))!= \
                                (OBD_FAILED | OBD_FAIL_ONCE)))

#define OBD_FAIL_CHECK_ONCE(id)                                              \
({      int _ret_ = 0;                                                       \
        if (OBD_FAIL_CHECK(id)) {                                            \
                CERROR("obd_fail_loc=%x\n", id);                             \
                obd_fail_loc |= OBD_FAILED;                                  \
                if ((id) & OBD_FAIL_ONCE)                                    \
                        obd_fail_loc |= OBD_FAIL_ONCE;                       \
                _ret_ = 1;                                                   \
        }                                                                    \
        _ret_;                                                               \
})

#define OBD_FAIL_RETURN(id, ret)                                             \
do {                                                                         \
        if (OBD_FAIL_CHECK_ONCE(id)) {                                       \
                RETURN(ret);                                                 \
        }                                                                    \
} while(0)

#define OBD_FAIL_GOTO(id, label, ret)                                        \
do {                                                                         \
        if (OBD_FAIL_CHECK_ONCE(id)) {                                       \
                GOTO(label, (ret));                                          \
        }                                                                    \
} while(0)

#define OBD_FAIL_TIMEOUT(id, secs)                                           \
do {                                                                         \
        if  (OBD_FAIL_CHECK_ONCE(id)) {                                      \
               CERROR("obd_fail_timeout id %x sleeping for %d secs\n",       \
                        (id), (secs));                                       \
                set_current_state(TASK_UNINTERRUPTIBLE);                     \
                schedule_timeout((secs) * HZ);                               \
                set_current_state(TASK_RUNNING);                             \
                CERROR("obd_fail_timeout id %x awake\n", (id));              \
       }                                                                     \
} while(0)

#ifdef __KERNEL__

/*
 * sleep_on() is known to be racy, using wait_event() interface instead as
 * recommended. --umka
 */
#define OBD_SLEEP_ON(wq)                                                     \
do {                                                                         \
        DEFINE_WAIT(__wait);                                                 \
        prepare_to_wait(&wq, &__wait, TASK_INTERRUPTIBLE);                   \
        schedule();                                                          \
        finish_wait(&wq, &__wait);                                           \
} while (0)

/* The idea here is to synchronise two threads to force a race. The
 * first thread that calls this with a matching fail_loc is put to
 * sleep. The next thread that calls with the same fail_loc wakes up
 * the first and continues. */
#define OBD_RACE(id)                                            \
do {                                                            \
        if  (OBD_FAIL_CHECK_ONCE(id)) {                         \
                CERROR("obd_race id %x sleeping\n", (id));      \
                OBD_SLEEP_ON(obd_race_waitq);                   \
                CERROR("obd_fail_race id %x awake\n", (id));    \
        } else if ((obd_fail_loc & OBD_FAIL_MASK_LOC) ==        \
                    ((id) & OBD_FAIL_MASK_LOC)) {               \
                wake_up(&obd_race_waitq);                       \
        }                                                       \
} while(0)
#else
/* sigh.  an expedient fix until OBD_RACE is fixed up */
#define OBD_RACE(foo) LBUG()
#endif

#define fixme() CDEBUG(D_OTHER, "FIXME\n");

#ifdef __KERNEL__
# include <linux/types.h>
# include <linux/blkdev.h>


# if (LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0))
#  define BDEVNAME_DECLARE_STORAGE(foo) char foo[BDEVNAME_SIZE]
#  define ll_bdevname(SB, STORAGE) __bdevname(kdev_t_to_nr(SB->s_dev), STORAGE)
#  define ll_lock_kernel lock_kernel()
#  define ll_sbdev(SB)    ((SB)->s_bdev)
#  define ll_sbdev_type      struct block_device *
#  define ll_sbdev_sync      fsync_bdev
# else
#  define BDEVNAME_DECLARE_STORAGE(foo) char __unused_##foo
#  define ll_sbdev(SB)    (kdev_t_to_nr((SB)->s_dev))
#  define ll_sbdev_type      kdev_t
#  define ll_sbdev_sync      fsync_dev
#  define ll_bdevname(SB,STORAGE) ((void)__unused_##STORAGE,bdevname(ll_sbdev(SB)))
#  define ll_lock_kernel
# endif

#ifdef HAVE_OLD_DEV_SET_RDONLY
  void dev_set_rdonly(ll_sbdev_type dev, int no_write);
  void dev_clear_rdonly(int no_write);
#else
  void dev_set_rdonly(ll_sbdev_type dev);
  void dev_clear_rdonly(ll_sbdev_type dev);
#endif
int dev_check_rdonly(ll_sbdev_type dev);
#define ll_check_rdonly(dev) dev_check_rdonly(dev)

static inline void ll_set_rdonly(ll_sbdev_type dev)
{
        CDEBUG(D_IOCTL | D_HA, "set dev %ld rdonly\n", (long)dev);
        ll_sbdev_sync(dev);
#ifdef HAVE_OLD_DEV_SET_RDONLY
        dev_set_rdonly(dev, 2);
#else
        dev_set_rdonly(dev);
#endif
}

static inline void ll_clear_rdonly(ll_sbdev_type dev)
{
        CDEBUG(D_IOCTL | D_HA, "unset dev %ld rdonly\n", (long)dev);
        if (ll_check_rdonly(dev)) {
                ll_sbdev_sync(dev);
#ifdef HAVE_OLD_DEV_SET_RDONLY
                dev_clear_rdonly(2);
#else
                dev_clear_rdonly(dev);
#endif
        }
}

static inline void OBD_FAIL_WRITE(int id, struct super_block *sb)
{
        if (OBD_FAIL_CHECK(id)) {
                BDEVNAME_DECLARE_STORAGE(tmp);
                CERROR("obd_fail_loc=%x, fail write operation on %s\n",
                       id, ll_bdevname(sb, tmp));
                ll_set_rdonly(ll_sbdev(sb));
                /* We set FAIL_ONCE because we never "un-fail" a device */
                obd_fail_loc |= OBD_FAILED | OBD_FAIL_ONCE;
        }
}
#else /* !__KERNEL__ */
# define LTIME_S(time) (time)
/* for obd_class.h */
# ifndef ERR_PTR
#  define ERR_PTR(a) ((void *)(a))
# endif
#endif  /* __KERNEL__ */

extern atomic_t portal_kmemory;

#if defined (CONFIG_DEBUG_MEMORY) && defined(__KERNEL__)
#define MEM_LOC_LEN 128

struct mem_track {
        struct hlist_node m_hash;
        char m_loc[MEM_LOC_LEN];
        void *m_ptr;
        int m_size;
};

void lvfs_memdbg_show(void);
void lvfs_memdbg_insert(struct mem_track *mt);
void lvfs_memdbg_remove(struct mem_track *mt);
struct mem_track *lvfs_memdbg_find(void *ptr);

int lvfs_memdbg_check_insert(struct mem_track *mt);
struct mem_track *lvfs_memdbg_check_remove(void *ptr);

static inline struct mem_track *
__new_mem_track(void *ptr, int size,
                char *file, int line)
{
        struct mem_track *mt;

        mt = kmalloc(sizeof(*mt), GFP_KERNEL);
        if (!mt)
                return NULL;

        snprintf(mt->m_loc, sizeof(mt->m_loc) - 1,
                 "%s:%d", file, line);

        mt->m_size = size;
        mt->m_ptr = ptr;
        return mt;
}

static inline void
__free_mem_track(struct mem_track *mt)
{
        kfree(mt);
}

static inline int
__get_mem_track(void *ptr, int size,
                char *file, int line)
{
        struct mem_track *mt;

        mt = __new_mem_track(ptr, size, file, line);
        if (!mt) {
                CWARN("can't allocate new memory track\n");
                return 0;
        }
        
        if (!lvfs_memdbg_check_insert(mt))
                __free_mem_track(mt);
        
        return 1;
}

static inline int
__put_mem_track(void *ptr, int size,
                char *file, int line)
{
        struct mem_track *mt;

        if (!(mt = lvfs_memdbg_check_remove(ptr))) {
                CWARN("ptr 0x%p is not allocated. Attempt to free "
                      "not allocated memory at %s:%d\n", ptr,
                      file, line);
                return 0;
        } else {
                if (mt->m_size != size) {
                        CWARN("freeing memory chunk of different size "
                              "than allocated (%d != %d) at %s:%d\n",
                              mt->m_size, size, file, line);
                }
                __free_mem_track(mt);
                return 1;
        }
}

#define get_mem_track(ptr, size, file, line)                                         \
        __get_mem_track((ptr), (size), (file), (line))

#define put_mem_track(ptr, size, file, line)                                         \
        __put_mem_track((ptr), (size), (file), (line))

#else /* !CONFIG_DEBUG_MEMORY */

#define get_mem_track(ptr, size, file, line)                                         \
        do {} while (0)

#define put_mem_track(ptr, size, file, line)                                         \
        do {} while (0)
#endif /* !CONFIG_DEBUG_MEMORY */

#define OBD_ALLOC_GFP(ptr, size, gfp_mask)                                           \
do {                                                                                 \
        (ptr) = kmalloc(size, (gfp_mask));                                           \
        if ((ptr) == NULL) {                                                         \
                CERROR("kmalloc of '" #ptr "' (%d bytes) failed at %s:%d\n",         \
                       (int)(size), __FILE__, __LINE__);                             \
                CERROR("%d total bytes allocated by Lustre, %d by Portals\n",        \
                       atomic_read(&obd_memory), atomic_read(&portal_kmemory));      \
        } else {                                                                     \
                memset(ptr, 0, size);                                                \
                atomic_add(size, &obd_memory);                                       \
                if (atomic_read(&obd_memory) > obd_memmax)                           \
                        obd_memmax = atomic_read(&obd_memory);                       \
                get_mem_track((ptr), (size), __FILE__, __LINE__);                    \
                CDEBUG(D_MALLOC, "kmalloced '" #ptr "': %d at %p (tot %d)\n",        \
                       (int)(size), (ptr), atomic_read(&obd_memory));                \
        }                                                                            \
} while (0)

#ifndef OBD_GFP_MASK
# define OBD_GFP_MASK GFP_NOFS
#endif

#define OBD_ALLOC(ptr, size) OBD_ALLOC_GFP(ptr, size, OBD_GFP_MASK)
#define OBD_ALLOC_WAIT(ptr, size) OBD_ALLOC_GFP(ptr, size, GFP_KERNEL)

#ifdef __arch_um__
# define OBD_VMALLOC(ptr, size) OBD_ALLOC(ptr, size)
#else
# define OBD_VMALLOC(ptr, size)                                                      \
do {                                                                                 \
        (ptr) = vmalloc(size);                                                       \
        if ((ptr) == NULL) {                                                         \
                CERROR("vmalloc of '" #ptr "' (%d bytes) failed at %s:%d\n",         \
                       (int)(size), __FILE__, __LINE__);                             \
                CERROR("%d total bytes allocated by Lustre, %d by Portals\n",        \
                       atomic_read(&obd_memory), atomic_read(&portal_kmemory));      \
        } else {                                                                     \
                memset(ptr, 0, size);                                                \
                atomic_add(size, &obd_memory);                                       \
                if (atomic_read(&obd_memory) > obd_memmax)                           \
                        obd_memmax = atomic_read(&obd_memory);                       \
                get_mem_track((ptr), (size), __FILE__, __LINE__);                    \
                CDEBUG(D_MALLOC, "vmalloced '" #ptr "': %d at %p (tot %d)\n",        \
                       (int)(size), ptr, atomic_read(&obd_memory));                  \
        }                                                                            \
} while (0)
#endif

#ifdef CONFIG_DEBUG_SLAB
#define POISON(ptr, c, s) do {} while (0)
#else
#define POISON(ptr, c, s) memset(ptr, c, s)
#endif

#if POISON_BULK
#define POISON_PAGE(page, val) do { memset(kmap(page), val, PAGE_SIZE);              \
                                    kunmap(page); } while (0)
#else
#define POISON_PAGE(page, val) do { } while (0)
#endif

#define OBD_FREE(ptr, size)                                                          \
do {                                                                                 \
        LASSERT(ptr);                                                                \
        put_mem_track((ptr), (size), __FILE__, __LINE__);                            \
        atomic_sub(size, &obd_memory);                                               \
        CDEBUG(D_MALLOC, "kfreed '" #ptr "': %d at %p (tot %d).\n",                  \
               (int)(size), ptr, atomic_read(&obd_memory));                          \
        POISON(ptr, 0x5a, size);                                                     \
        kfree(ptr);                                                                  \
        (ptr) = (void *)0xdeadbeef;                                                  \
} while (0)

#ifdef __arch_um__
# define OBD_VFREE(ptr, size) OBD_FREE(ptr, size)
#else
# define OBD_VFREE(ptr, size)                                                        \
do {                                                                                 \
        LASSERT(ptr);                                                                \
        put_mem_track((ptr), (size), __FILE__, __LINE__);                            \
        atomic_sub(size, &obd_memory);                                               \
        CDEBUG(D_MALLOC, "vfreed '" #ptr "': %d at %p (tot %d).\n",                  \
               (int)(size), ptr, atomic_read(&obd_memory));                          \
        POISON(ptr, 0x5a, size);                                                     \
        vfree(ptr);                                                                  \
        (ptr) = (void *)0xdeadbeef;                                                  \
} while (0)
#endif

/*
 * we memset() the slab object to 0 when allocation succeeds, so DO NOT HAVE A
 * CTOR THAT DOES ANYTHING. Its work will be cleared here. We'd love to assert
 * on that, but slab.c keeps kmem_cache_s all to itself.
 */
#define OBD_SLAB_ALLOC(ptr, slab, type, size)                                         \
do {                                                                                  \
        LASSERT(!in_interrupt());                                                     \
        (ptr) = kmem_cache_alloc(slab, (type));                                       \
        if ((ptr) == NULL) {                                                          \
                CERROR("slab-alloc of '"#ptr"' (%d bytes) failed at %s:%d\n",         \
                       (int)(size), __FILE__, __LINE__);                              \
                CERROR("%d total bytes allocated by Lustre, %d by Portals\n",         \
                       atomic_read(&obd_memory), atomic_read(&portal_kmemory));       \
        } else {                                                                      \
                memset(ptr, 0, size);                                                 \
                atomic_add(size, &obd_memory);                                        \
                if (atomic_read(&obd_memory) > obd_memmax)                            \
                        obd_memmax = atomic_read(&obd_memory);                        \
                get_mem_track((ptr), (size), __FILE__, __LINE__);                     \
                CDEBUG(D_MALLOC, "slab-alloced '"#ptr"': %d at %p (tot %d)\n",        \
                       (int)(size), ptr, atomic_read(&obd_memory));                   \
        }                                                                             \
} while (0)

#define OBD_SLAB_FREE(ptr, slab, size)                                                \
do {                                                                                  \
        LASSERT(ptr);                                                                 \
        CDEBUG(D_MALLOC, "slab-freed '" #ptr "': %d at %p (tot %d).\n",               \
               (int)(size), ptr, atomic_read(&obd_memory));                           \
        put_mem_track((ptr), (size), __FILE__, __LINE__);                             \
        atomic_sub(size, &obd_memory);                                                \
        POISON(ptr, 0x5a, size);                                                      \
        kmem_cache_free(slab, ptr);                                                   \
        (ptr) = (void *)0xdeadbeef;                                                   \
} while (0)

#endif