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gfiber / kernel / lockdown / a37a38b10c719b4181e45d8ab75bc2d3b681a63d / . / drivers / staging / lustre / lustre / ptlrpc / sec_bulk.c
blob: c05a8554d737dcea467e945537299ce9a0ab4446 [file] [log] [blame]
/*
* 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/ptlrpc/sec_bulk.c
*
* Author: Eric Mei <ericm@clusterfs.com>
*/
#define DEBUG_SUBSYSTEM S_SEC
#include "../../include/linux/libcfs/libcfs.h"
#include <linux/crypto.h>
#include "../include/obd.h"
#include "../include/obd_cksum.h"
#include "../include/obd_class.h"
#include "../include/obd_support.h"
#include "../include/lustre_net.h"
#include "../include/lustre_import.h"
#include "../include/lustre_dlm.h"
#include "../include/lustre_sec.h"
#include "ptlrpc_internal.h"
/****************************************
* bulk encryption page pools *
****************************************/
#define POINTERS_PER_PAGE (PAGE_CACHE_SIZE / sizeof(void *))
#define PAGES_PER_POOL (POINTERS_PER_PAGE)
#define IDLE_IDX_MAX (100)
#define IDLE_IDX_WEIGHT (3)
#define CACHE_QUIESCENT_PERIOD (20)
static struct ptlrpc_enc_page_pool {
/*
* constants
*/
unsigned long epp_max_pages; /* maximum pages can hold, const */
unsigned int epp_max_pools; /* number of pools, const */
/*
* wait queue in case of not enough free pages.
*/
wait_queue_head_t epp_waitq; /* waiting threads */
unsigned int epp_waitqlen; /* wait queue length */
unsigned long epp_pages_short; /* # of pages wanted of in-q users */
unsigned int epp_growing:1; /* during adding pages */
/*
* indicating how idle the pools are, from 0 to MAX_IDLE_IDX
* this is counted based on each time when getting pages from
* the pools, not based on time. which means in case that system
* is idled for a while but the idle_idx might still be low if no
* activities happened in the pools.
*/
unsigned long epp_idle_idx;
/* last shrink time due to mem tight */
long epp_last_shrink;
long epp_last_access;
/*
* in-pool pages bookkeeping
*/
spinlock_t epp_lock; /* protect following fields */
unsigned long epp_total_pages; /* total pages in pools */
unsigned long epp_free_pages; /* current pages available */
/*
* statistics
*/
unsigned long epp_st_max_pages; /* # of pages ever reached */
unsigned int epp_st_grows; /* # of grows */
unsigned int epp_st_grow_fails; /* # of add pages failures */
unsigned int epp_st_shrinks; /* # of shrinks */
unsigned long epp_st_access; /* # of access */
unsigned long epp_st_missings; /* # of cache missing */
unsigned long epp_st_lowfree; /* lowest free pages reached */
unsigned int epp_st_max_wqlen; /* highest waitqueue length */
unsigned long epp_st_max_wait; /* in jiffies */
/*
* pointers to pools
*/
struct page ***epp_pools;
} page_pools;
/*
* /proc/fs/lustre/sptlrpc/encrypt_page_pools
*/
int sptlrpc_proc_enc_pool_seq_show(struct seq_file *m, void *v)
{
spin_lock(&page_pools.epp_lock);
seq_printf(m,
"physical pages: %lu\n"
"pages per pool: %lu\n"
"max pages: %lu\n"
"max pools: %u\n"
"total pages: %lu\n"
"total free: %lu\n"
"idle index: %lu/100\n"
"last shrink: %lds\n"
"last access: %lds\n"
"max pages reached: %lu\n"
"grows: %u\n"
"grows failure: %u\n"
"shrinks: %u\n"
"cache access: %lu\n"
"cache missing: %lu\n"
"low free mark: %lu\n"
"max waitqueue depth: %u\n"
"max wait time: " CFS_TIME_T "/%u\n",
totalram_pages,
PAGES_PER_POOL,
page_pools.epp_max_pages,
page_pools.epp_max_pools,
page_pools.epp_total_pages,
page_pools.epp_free_pages,
page_pools.epp_idle_idx,
get_seconds() - page_pools.epp_last_shrink,
get_seconds() - page_pools.epp_last_access,
page_pools.epp_st_max_pages,
page_pools.epp_st_grows,
page_pools.epp_st_grow_fails,
page_pools.epp_st_shrinks,
page_pools.epp_st_access,
page_pools.epp_st_missings,
page_pools.epp_st_lowfree,
page_pools.epp_st_max_wqlen,
page_pools.epp_st_max_wait,
HZ);
spin_unlock(&page_pools.epp_lock);
return 0;
}
static void enc_pools_release_free_pages(long npages)
{
int p_idx, g_idx;
int p_idx_max1, p_idx_max2;
LASSERT(npages > 0);
LASSERT(npages <= page_pools.epp_free_pages);
LASSERT(page_pools.epp_free_pages <= page_pools.epp_total_pages);
/* max pool index before the release */
p_idx_max2 = (page_pools.epp_total_pages - 1) / PAGES_PER_POOL;
page_pools.epp_free_pages -= npages;
page_pools.epp_total_pages -= npages;
/* max pool index after the release */
p_idx_max1 = page_pools.epp_total_pages == 0 ? -1 :
((page_pools.epp_total_pages - 1) / PAGES_PER_POOL);
p_idx = page_pools.epp_free_pages / PAGES_PER_POOL;
g_idx = page_pools.epp_free_pages % PAGES_PER_POOL;
LASSERT(page_pools.epp_pools[p_idx]);
while (npages--) {
LASSERT(page_pools.epp_pools[p_idx]);
LASSERT(page_pools.epp_pools[p_idx][g_idx] != NULL);
__free_page(page_pools.epp_pools[p_idx][g_idx]);
page_pools.epp_pools[p_idx][g_idx] = NULL;
if (++g_idx == PAGES_PER_POOL) {
p_idx++;
g_idx = 0;
}
}
/* free unused pools */
while (p_idx_max1 < p_idx_max2) {
LASSERT(page_pools.epp_pools[p_idx_max2]);
OBD_FREE(page_pools.epp_pools[p_idx_max2], PAGE_CACHE_SIZE);
page_pools.epp_pools[p_idx_max2] = NULL;
p_idx_max2--;
}
}
/*
* we try to keep at least PTLRPC_MAX_BRW_PAGES pages in the pool.
*/
static unsigned long enc_pools_shrink_count(struct shrinker *s,
struct shrink_control *sc)
{
/*
* if no pool access for a long time, we consider it's fully idle.
* a little race here is fine.
*/
if (unlikely(get_seconds() - page_pools.epp_last_access >
CACHE_QUIESCENT_PERIOD)) {
spin_lock(&page_pools.epp_lock);
page_pools.epp_idle_idx = IDLE_IDX_MAX;
spin_unlock(&page_pools.epp_lock);
}
LASSERT(page_pools.epp_idle_idx <= IDLE_IDX_MAX);
return max((int)page_pools.epp_free_pages - PTLRPC_MAX_BRW_PAGES, 0) *
(IDLE_IDX_MAX - page_pools.epp_idle_idx) / IDLE_IDX_MAX;
}
/*
* we try to keep at least PTLRPC_MAX_BRW_PAGES pages in the pool.
*/
static unsigned long enc_pools_shrink_scan(struct shrinker *s,
struct shrink_control *sc)
{
spin_lock(&page_pools.epp_lock);
sc->nr_to_scan = min_t(unsigned long, sc->nr_to_scan,
page_pools.epp_free_pages - PTLRPC_MAX_BRW_PAGES);
if (sc->nr_to_scan > 0) {
enc_pools_release_free_pages(sc->nr_to_scan);
CDEBUG(D_SEC, "released %ld pages, %ld left\n",
(long)sc->nr_to_scan, page_pools.epp_free_pages);
page_pools.epp_st_shrinks++;
page_pools.epp_last_shrink = get_seconds();
}
spin_unlock(&page_pools.epp_lock);
/*
* if no pool access for a long time, we consider it's fully idle.
* a little race here is fine.
*/
if (unlikely(get_seconds() - page_pools.epp_last_access >
CACHE_QUIESCENT_PERIOD)) {
spin_lock(&page_pools.epp_lock);
page_pools.epp_idle_idx = IDLE_IDX_MAX;
spin_unlock(&page_pools.epp_lock);
}
LASSERT(page_pools.epp_idle_idx <= IDLE_IDX_MAX);
return sc->nr_to_scan;
}
static inline
int npages_to_npools(unsigned long npages)
{
return (int) ((npages + PAGES_PER_POOL - 1) / PAGES_PER_POOL);
}
/*
* return how many pages cleaned up.
*/
static unsigned long enc_pools_cleanup(struct page ***pools, int npools)
{
unsigned long cleaned = 0;
int i, j;
for (i = 0; i < npools; i++) {
if (pools[i]) {
for (j = 0; j < PAGES_PER_POOL; j++) {
if (pools[i][j]) {
__free_page(pools[i][j]);
cleaned++;
}
}
OBD_FREE(pools[i], PAGE_CACHE_SIZE);
pools[i] = NULL;
}
}
return cleaned;
}
/*
* merge @npools pointed by @pools which contains @npages new pages
* into current pools.
*
* we have options to avoid most memory copy with some tricks. but we choose
* the simplest way to avoid complexity. It's not frequently called.
*/
static void enc_pools_insert(struct page ***pools, int npools, int npages)
{
int freeslot;
int op_idx, np_idx, og_idx, ng_idx;
int cur_npools, end_npools;
LASSERT(npages > 0);
LASSERT(page_pools.epp_total_pages+npages <= page_pools.epp_max_pages);
LASSERT(npages_to_npools(npages) == npools);
LASSERT(page_pools.epp_growing);
spin_lock(&page_pools.epp_lock);
/*
* (1) fill all the free slots of current pools.
*/
/* free slots are those left by rent pages, and the extra ones with
* index >= total_pages, locate at the tail of last pool. */
freeslot = page_pools.epp_total_pages % PAGES_PER_POOL;
if (freeslot != 0)
freeslot = PAGES_PER_POOL - freeslot;
freeslot += page_pools.epp_total_pages - page_pools.epp_free_pages;
op_idx = page_pools.epp_free_pages / PAGES_PER_POOL;
og_idx = page_pools.epp_free_pages % PAGES_PER_POOL;
np_idx = npools - 1;
ng_idx = (npages - 1) % PAGES_PER_POOL;
while (freeslot) {
LASSERT(page_pools.epp_pools[op_idx][og_idx] == NULL);
LASSERT(pools[np_idx][ng_idx] != NULL);
page_pools.epp_pools[op_idx][og_idx] = pools[np_idx][ng_idx];
pools[np_idx][ng_idx] = NULL;
freeslot--;
if (++og_idx == PAGES_PER_POOL) {
op_idx++;
og_idx = 0;
}
if (--ng_idx < 0) {
if (np_idx == 0)
break;
np_idx--;
ng_idx = PAGES_PER_POOL - 1;
}
}
/*
* (2) add pools if needed.
*/
cur_npools = (page_pools.epp_total_pages + PAGES_PER_POOL - 1) /
PAGES_PER_POOL;
end_npools = (page_pools.epp_total_pages + npages + PAGES_PER_POOL - 1)
/ PAGES_PER_POOL;
LASSERT(end_npools <= page_pools.epp_max_pools);
np_idx = 0;
while (cur_npools < end_npools) {
LASSERT(page_pools.epp_pools[cur_npools] == NULL);
LASSERT(np_idx < npools);
LASSERT(pools[np_idx] != NULL);
page_pools.epp_pools[cur_npools++] = pools[np_idx];
pools[np_idx++] = NULL;
}
page_pools.epp_total_pages += npages;
page_pools.epp_free_pages += npages;
page_pools.epp_st_lowfree = page_pools.epp_free_pages;
if (page_pools.epp_total_pages > page_pools.epp_st_max_pages)
page_pools.epp_st_max_pages = page_pools.epp_total_pages;
CDEBUG(D_SEC, "add %d pages to total %lu\n", npages,
page_pools.epp_total_pages);
spin_unlock(&page_pools.epp_lock);
}
static int enc_pools_add_pages(int npages)
{
static DEFINE_MUTEX(add_pages_mutex);
struct page ***pools;
int npools, alloced = 0;
int i, j, rc = -ENOMEM;
if (npages < PTLRPC_MAX_BRW_PAGES)
npages = PTLRPC_MAX_BRW_PAGES;
mutex_lock(&add_pages_mutex);
if (npages + page_pools.epp_total_pages > page_pools.epp_max_pages)
npages = page_pools.epp_max_pages - page_pools.epp_total_pages;
LASSERT(npages > 0);
page_pools.epp_st_grows++;
npools = npages_to_npools(npages);
OBD_ALLOC(pools, npools * sizeof(*pools));
if (pools == NULL)
goto out;
for (i = 0; i < npools; i++) {
OBD_ALLOC(pools[i], PAGE_CACHE_SIZE);
if (pools[i] == NULL)
goto out_pools;
for (j = 0; j < PAGES_PER_POOL && alloced < npages; j++) {
pools[i][j] = alloc_page(GFP_NOFS |
__GFP_HIGHMEM);
if (pools[i][j] == NULL)
goto out_pools;
alloced++;
}
}
LASSERT(alloced == npages);
enc_pools_insert(pools, npools, npages);
CDEBUG(D_SEC, "added %d pages into pools\n", npages);
rc = 0;
out_pools:
enc_pools_cleanup(pools, npools);
OBD_FREE(pools, npools * sizeof(*pools));
out:
if (rc) {
page_pools.epp_st_grow_fails++;
CERROR("Failed to allocate %d enc pages\n", npages);
}
mutex_unlock(&add_pages_mutex);
return rc;
}
static inline void enc_pools_wakeup(void)
{
assert_spin_locked(&page_pools.epp_lock);
LASSERT(page_pools.epp_waitqlen >= 0);
if (unlikely(page_pools.epp_waitqlen)) {
LASSERT(waitqueue_active(&page_pools.epp_waitq));
wake_up_all(&page_pools.epp_waitq);
}
}
static int enc_pools_should_grow(int page_needed, long now)
{
/* don't grow if someone else is growing the pools right now,
* or the pools has reached its full capacity
*/
if (page_pools.epp_growing ||
page_pools.epp_total_pages == page_pools.epp_max_pages)
return 0;
/* if total pages is not enough, we need to grow */
if (page_pools.epp_total_pages < page_needed)
return 1;
/*
* we wanted to return 0 here if there was a shrink just happened
* moment ago, but this may cause deadlock if both client and ost
* live on single node.
*/
#if 0
if (now - page_pools.epp_last_shrink < 2)
return 0;
#endif
/*
* here we perhaps need consider other factors like wait queue
* length, idle index, etc. ?
*/
/* grow the pools in any other cases */
return 1;
}
/*
* we allocate the requested pages atomically.
*/
int sptlrpc_enc_pool_get_pages(struct ptlrpc_bulk_desc *desc)
{
wait_queue_t waitlink;
unsigned long this_idle = -1;
unsigned long tick = 0;
long now;
int p_idx, g_idx;
int i;
LASSERT(desc->bd_iov_count > 0);
LASSERT(desc->bd_iov_count <= page_pools.epp_max_pages);
/* resent bulk, enc iov might have been allocated previously */
if (desc->bd_enc_iov != NULL)
return 0;
OBD_ALLOC(desc->bd_enc_iov,
desc->bd_iov_count * sizeof(*desc->bd_enc_iov));
if (desc->bd_enc_iov == NULL)
return -ENOMEM;
spin_lock(&page_pools.epp_lock);
page_pools.epp_st_access++;
again:
if (unlikely(page_pools.epp_free_pages < desc->bd_iov_count)) {
if (tick == 0)
tick = cfs_time_current();
now = get_seconds();
page_pools.epp_st_missings++;
page_pools.epp_pages_short += desc->bd_iov_count;
if (enc_pools_should_grow(desc->bd_iov_count, now)) {
page_pools.epp_growing = 1;
spin_unlock(&page_pools.epp_lock);
enc_pools_add_pages(page_pools.epp_pages_short / 2);
spin_lock(&page_pools.epp_lock);
page_pools.epp_growing = 0;
enc_pools_wakeup();
} else {
if (++page_pools.epp_waitqlen >
page_pools.epp_st_max_wqlen)
page_pools.epp_st_max_wqlen =
page_pools.epp_waitqlen;
set_current_state(TASK_UNINTERRUPTIBLE);
init_waitqueue_entry(&waitlink, current);
add_wait_queue(&page_pools.epp_waitq, &waitlink);
spin_unlock(&page_pools.epp_lock);
schedule();
remove_wait_queue(&page_pools.epp_waitq, &waitlink);
LASSERT(page_pools.epp_waitqlen > 0);
spin_lock(&page_pools.epp_lock);
page_pools.epp_waitqlen--;
}
LASSERT(page_pools.epp_pages_short >= desc->bd_iov_count);
page_pools.epp_pages_short -= desc->bd_iov_count;
this_idle = 0;
goto again;
}
/* record max wait time */
if (unlikely(tick != 0)) {
tick = cfs_time_current() - tick;
if (tick > page_pools.epp_st_max_wait)
page_pools.epp_st_max_wait = tick;
}
/* proceed with rest of allocation */
page_pools.epp_free_pages -= desc->bd_iov_count;
p_idx = page_pools.epp_free_pages / PAGES_PER_POOL;
g_idx = page_pools.epp_free_pages % PAGES_PER_POOL;
for (i = 0; i < desc->bd_iov_count; i++) {
LASSERT(page_pools.epp_pools[p_idx][g_idx] != NULL);
desc->bd_enc_iov[i].kiov_page =
page_pools.epp_pools[p_idx][g_idx];
page_pools.epp_pools[p_idx][g_idx] = NULL;
if (++g_idx == PAGES_PER_POOL) {
p_idx++;
g_idx = 0;
}
}
if (page_pools.epp_free_pages < page_pools.epp_st_lowfree)
page_pools.epp_st_lowfree = page_pools.epp_free_pages;
/*
* new idle index = (old * weight + new) / (weight + 1)
*/
if (this_idle == -1) {
this_idle = page_pools.epp_free_pages * IDLE_IDX_MAX /
page_pools.epp_total_pages;
}
page_pools.epp_idle_idx = (page_pools.epp_idle_idx * IDLE_IDX_WEIGHT +
this_idle) /
(IDLE_IDX_WEIGHT + 1);
page_pools.epp_last_access = get_seconds();
spin_unlock(&page_pools.epp_lock);
return 0;
}
EXPORT_SYMBOL(sptlrpc_enc_pool_get_pages);
void sptlrpc_enc_pool_put_pages(struct ptlrpc_bulk_desc *desc)
{
int p_idx, g_idx;
int i;
if (desc->bd_enc_iov == NULL)
return;
LASSERT(desc->bd_iov_count > 0);
spin_lock(&page_pools.epp_lock);
p_idx = page_pools.epp_free_pages / PAGES_PER_POOL;
g_idx = page_pools.epp_free_pages % PAGES_PER_POOL;
LASSERT(page_pools.epp_free_pages + desc->bd_iov_count <=
page_pools.epp_total_pages);
LASSERT(page_pools.epp_pools[p_idx]);
for (i = 0; i < desc->bd_iov_count; i++) {
LASSERT(desc->bd_enc_iov[i].kiov_page != NULL);
LASSERT(g_idx != 0 || page_pools.epp_pools[p_idx]);
LASSERT(page_pools.epp_pools[p_idx][g_idx] == NULL);
page_pools.epp_pools[p_idx][g_idx] =
desc->bd_enc_iov[i].kiov_page;
if (++g_idx == PAGES_PER_POOL) {
p_idx++;
g_idx = 0;
}
}
page_pools.epp_free_pages += desc->bd_iov_count;
enc_pools_wakeup();
spin_unlock(&page_pools.epp_lock);
OBD_FREE(desc->bd_enc_iov,
desc->bd_iov_count * sizeof(*desc->bd_enc_iov));
desc->bd_enc_iov = NULL;
}
EXPORT_SYMBOL(sptlrpc_enc_pool_put_pages);
/*
* we don't do much stuff for add_user/del_user anymore, except adding some
* initial pages in add_user() if current pools are empty, rest would be
* handled by the pools's self-adaption.
*/
int sptlrpc_enc_pool_add_user(void)
{
int need_grow = 0;
spin_lock(&page_pools.epp_lock);
if (page_pools.epp_growing == 0 && page_pools.epp_total_pages == 0) {
page_pools.epp_growing = 1;
need_grow = 1;
}
spin_unlock(&page_pools.epp_lock);
if (need_grow) {
enc_pools_add_pages(PTLRPC_MAX_BRW_PAGES +
PTLRPC_MAX_BRW_PAGES);
spin_lock(&page_pools.epp_lock);
page_pools.epp_growing = 0;
enc_pools_wakeup();
spin_unlock(&page_pools.epp_lock);
}
return 0;
}
EXPORT_SYMBOL(sptlrpc_enc_pool_add_user);
int sptlrpc_enc_pool_del_user(void)
{
return 0;
}
EXPORT_SYMBOL(sptlrpc_enc_pool_del_user);
static inline void enc_pools_alloc(void)
{
LASSERT(page_pools.epp_max_pools);
OBD_ALLOC_LARGE(page_pools.epp_pools,
page_pools.epp_max_pools *
sizeof(*page_pools.epp_pools));
}
static inline void enc_pools_free(void)
{
LASSERT(page_pools.epp_max_pools);
LASSERT(page_pools.epp_pools);
OBD_FREE_LARGE(page_pools.epp_pools,
page_pools.epp_max_pools *
sizeof(*page_pools.epp_pools));
}
static struct shrinker pools_shrinker = {
.count_objects = enc_pools_shrink_count,
.scan_objects = enc_pools_shrink_scan,
.seeks = DEFAULT_SEEKS,
};
int sptlrpc_enc_pool_init(void)
{
/*
* maximum capacity is 1/8 of total physical memory.
* is the 1/8 a good number?
*/
page_pools.epp_max_pages = totalram_pages / 8;
page_pools.epp_max_pools = npages_to_npools(page_pools.epp_max_pages);
init_waitqueue_head(&page_pools.epp_waitq);
page_pools.epp_waitqlen = 0;
page_pools.epp_pages_short = 0;
page_pools.epp_growing = 0;
page_pools.epp_idle_idx = 0;
page_pools.epp_last_shrink = get_seconds();
page_pools.epp_last_access = get_seconds();
spin_lock_init(&page_pools.epp_lock);
page_pools.epp_total_pages = 0;
page_pools.epp_free_pages = 0;
page_pools.epp_st_max_pages = 0;
page_pools.epp_st_grows = 0;
page_pools.epp_st_grow_fails = 0;
page_pools.epp_st_shrinks = 0;
page_pools.epp_st_access = 0;
page_pools.epp_st_missings = 0;
page_pools.epp_st_lowfree = 0;
page_pools.epp_st_max_wqlen = 0;
page_pools.epp_st_max_wait = 0;
enc_pools_alloc();
if (page_pools.epp_pools == NULL)
return -ENOMEM;
register_shrinker(&pools_shrinker);
return 0;
}
void sptlrpc_enc_pool_fini(void)
{
unsigned long cleaned, npools;
LASSERT(page_pools.epp_pools);
LASSERT(page_pools.epp_total_pages == page_pools.epp_free_pages);
unregister_shrinker(&pools_shrinker);
npools = npages_to_npools(page_pools.epp_total_pages);
cleaned = enc_pools_cleanup(page_pools.epp_pools, npools);
LASSERT(cleaned == page_pools.epp_total_pages);
enc_pools_free();
if (page_pools.epp_st_access > 0) {
CDEBUG(D_SEC,
"max pages %lu, grows %u, grow fails %u, shrinks %u, access %lu, missing %lu, max qlen %u, max wait "
CFS_TIME_T"/%d\n",
page_pools.epp_st_max_pages, page_pools.epp_st_grows,
page_pools.epp_st_grow_fails,
page_pools.epp_st_shrinks, page_pools.epp_st_access,
page_pools.epp_st_missings, page_pools.epp_st_max_wqlen,
page_pools.epp_st_max_wait, HZ);
}
}
static int cfs_hash_alg_id[] = {
[BULK_HASH_ALG_NULL] = CFS_HASH_ALG_NULL,
[BULK_HASH_ALG_ADLER32] = CFS_HASH_ALG_ADLER32,
[BULK_HASH_ALG_CRC32] = CFS_HASH_ALG_CRC32,
[BULK_HASH_ALG_MD5] = CFS_HASH_ALG_MD5,
[BULK_HASH_ALG_SHA1] = CFS_HASH_ALG_SHA1,
[BULK_HASH_ALG_SHA256] = CFS_HASH_ALG_SHA256,
[BULK_HASH_ALG_SHA384] = CFS_HASH_ALG_SHA384,
[BULK_HASH_ALG_SHA512] = CFS_HASH_ALG_SHA512,
};
const char *sptlrpc_get_hash_name(__u8 hash_alg)
{
return cfs_crypto_hash_name(cfs_hash_alg_id[hash_alg]);
}
EXPORT_SYMBOL(sptlrpc_get_hash_name);
__u8 sptlrpc_get_hash_alg(const char *algname)
{
return cfs_crypto_hash_alg(algname);
}
EXPORT_SYMBOL(sptlrpc_get_hash_alg);
int bulk_sec_desc_unpack(struct lustre_msg *msg, int offset, int swabbed)
{
struct ptlrpc_bulk_sec_desc *bsd;
int size = msg->lm_buflens[offset];
bsd = lustre_msg_buf(msg, offset, sizeof(*bsd));
if (bsd == NULL) {
CERROR("Invalid bulk sec desc: size %d\n", size);
return -EINVAL;
}
if (swabbed)
__swab32s(&bsd->bsd_nob);
if (unlikely(bsd->bsd_version != 0)) {
CERROR("Unexpected version %u\n", bsd->bsd_version);
return -EPROTO;
}
if (unlikely(bsd->bsd_type >= SPTLRPC_BULK_MAX)) {
CERROR("Invalid type %u\n", bsd->bsd_type);
return -EPROTO;
}
/* FIXME more sanity check here */
if (unlikely(bsd->bsd_svc != SPTLRPC_BULK_SVC_NULL &&
bsd->bsd_svc != SPTLRPC_BULK_SVC_INTG &&
bsd->bsd_svc != SPTLRPC_BULK_SVC_PRIV)) {
CERROR("Invalid svc %u\n", bsd->bsd_svc);
return -EPROTO;
}
return 0;
}
EXPORT_SYMBOL(bulk_sec_desc_unpack);
int sptlrpc_get_bulk_checksum(struct ptlrpc_bulk_desc *desc, __u8 alg,
void *buf, int buflen)
{
struct cfs_crypto_hash_desc *hdesc;
int hashsize;
char hashbuf[64];
unsigned int bufsize;
int i, err;
LASSERT(alg > BULK_HASH_ALG_NULL && alg < BULK_HASH_ALG_MAX);
LASSERT(buflen >= 4);
hdesc = cfs_crypto_hash_init(cfs_hash_alg_id[alg], NULL, 0);
if (IS_ERR(hdesc)) {
CERROR("Unable to initialize checksum hash %s\n",
cfs_crypto_hash_name(cfs_hash_alg_id[alg]));
return PTR_ERR(hdesc);
}
hashsize = cfs_crypto_hash_digestsize(cfs_hash_alg_id[alg]);
for (i = 0; i < desc->bd_iov_count; i++) {
cfs_crypto_hash_update_page(hdesc, desc->bd_iov[i].kiov_page,
desc->bd_iov[i].kiov_offset & ~CFS_PAGE_MASK,
desc->bd_iov[i].kiov_len);
}
if (hashsize > buflen) {
bufsize = sizeof(hashbuf);
err = cfs_crypto_hash_final(hdesc, (unsigned char *)hashbuf,
&bufsize);
memcpy(buf, hashbuf, buflen);
} else {
bufsize = buflen;
err = cfs_crypto_hash_final(hdesc, (unsigned char *)buf,
&bufsize);
}
if (err)
cfs_crypto_hash_final(hdesc, NULL, NULL);
return err;
}
EXPORT_SYMBOL(sptlrpc_get_bulk_checksum);