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nest-open-source / nest-learning-thermostat / 5.7.1 / linux-imx-ul / refs/heads/master / . / drivers / staging / lustre / lustre / ptlrpc / sec.c
blob: 21e9dc9d5580b35c2029712b44d637a0f9dd223f [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.c
*
* Author: Eric Mei <ericm@clusterfs.com>
*/
#define DEBUG_SUBSYSTEM S_SEC
#include "../../include/linux/libcfs/libcfs.h"
#include <linux/crypto.h>
#include <linux/key.h>
#include "../include/obd.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"
/***********************************************
* policy registers *
***********************************************/
static rwlock_t policy_lock;
static struct ptlrpc_sec_policy *policies[SPTLRPC_POLICY_MAX] = {
NULL,
};
int sptlrpc_register_policy(struct ptlrpc_sec_policy *policy)
{
__u16 number = policy->sp_policy;
LASSERT(policy->sp_name);
LASSERT(policy->sp_cops);
LASSERT(policy->sp_sops);
if (number >= SPTLRPC_POLICY_MAX)
return -EINVAL;
write_lock(&policy_lock);
if (unlikely(policies[number])) {
write_unlock(&policy_lock);
return -EALREADY;
}
policies[number] = policy;
write_unlock(&policy_lock);
CDEBUG(D_SEC, "%s: registered\n", policy->sp_name);
return 0;
}
EXPORT_SYMBOL(sptlrpc_register_policy);
int sptlrpc_unregister_policy(struct ptlrpc_sec_policy *policy)
{
__u16 number = policy->sp_policy;
LASSERT(number < SPTLRPC_POLICY_MAX);
write_lock(&policy_lock);
if (unlikely(policies[number] == NULL)) {
write_unlock(&policy_lock);
CERROR("%s: already unregistered\n", policy->sp_name);
return -EINVAL;
}
LASSERT(policies[number] == policy);
policies[number] = NULL;
write_unlock(&policy_lock);
CDEBUG(D_SEC, "%s: unregistered\n", policy->sp_name);
return 0;
}
EXPORT_SYMBOL(sptlrpc_unregister_policy);
static
struct ptlrpc_sec_policy *sptlrpc_wireflavor2policy(__u32 flavor)
{
static DEFINE_MUTEX(load_mutex);
static atomic_t loaded = ATOMIC_INIT(0);
struct ptlrpc_sec_policy *policy;
__u16 number = SPTLRPC_FLVR_POLICY(flavor);
__u16 flag = 0;
if (number >= SPTLRPC_POLICY_MAX)
return NULL;
while (1) {
read_lock(&policy_lock);
policy = policies[number];
if (policy && !try_module_get(policy->sp_owner))
policy = NULL;
if (policy == NULL)
flag = atomic_read(&loaded);
read_unlock(&policy_lock);
if (policy != NULL || flag != 0 ||
number != SPTLRPC_POLICY_GSS)
break;
/* try to load gss module, once */
mutex_lock(&load_mutex);
if (atomic_read(&loaded) == 0) {
if (request_module("ptlrpc_gss") == 0)
CDEBUG(D_SEC,
"module ptlrpc_gss loaded on demand\n");
else
CERROR("Unable to load module ptlrpc_gss\n");
atomic_set(&loaded, 1);
}
mutex_unlock(&load_mutex);
}
return policy;
}
__u32 sptlrpc_name2flavor_base(const char *name)
{
if (!strcmp(name, "null"))
return SPTLRPC_FLVR_NULL;
if (!strcmp(name, "plain"))
return SPTLRPC_FLVR_PLAIN;
if (!strcmp(name, "krb5n"))
return SPTLRPC_FLVR_KRB5N;
if (!strcmp(name, "krb5a"))
return SPTLRPC_FLVR_KRB5A;
if (!strcmp(name, "krb5i"))
return SPTLRPC_FLVR_KRB5I;
if (!strcmp(name, "krb5p"))
return SPTLRPC_FLVR_KRB5P;
return SPTLRPC_FLVR_INVALID;
}
EXPORT_SYMBOL(sptlrpc_name2flavor_base);
const char *sptlrpc_flavor2name_base(__u32 flvr)
{
__u32 base = SPTLRPC_FLVR_BASE(flvr);
if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_NULL))
return "null";
else if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_PLAIN))
return "plain";
else if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_KRB5N))
return "krb5n";
else if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_KRB5A))
return "krb5a";
else if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_KRB5I))
return "krb5i";
else if (base == SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_KRB5P))
return "krb5p";
CERROR("invalid wire flavor 0x%x\n", flvr);
return "invalid";
}
EXPORT_SYMBOL(sptlrpc_flavor2name_base);
char *sptlrpc_flavor2name_bulk(struct sptlrpc_flavor *sf,
char *buf, int bufsize)
{
if (SPTLRPC_FLVR_POLICY(sf->sf_rpc) == SPTLRPC_POLICY_PLAIN)
snprintf(buf, bufsize, "hash:%s",
sptlrpc_get_hash_name(sf->u_bulk.hash.hash_alg));
else
snprintf(buf, bufsize, "%s",
sptlrpc_flavor2name_base(sf->sf_rpc));
buf[bufsize - 1] = '\0';
return buf;
}
EXPORT_SYMBOL(sptlrpc_flavor2name_bulk);
char *sptlrpc_flavor2name(struct sptlrpc_flavor *sf, char *buf, int bufsize)
{
strlcpy(buf, sptlrpc_flavor2name_base(sf->sf_rpc), bufsize);
/*
* currently we don't support customized bulk specification for
* flavors other than plain
*/
if (SPTLRPC_FLVR_POLICY(sf->sf_rpc) == SPTLRPC_POLICY_PLAIN) {
char bspec[16];
bspec[0] = '-';
sptlrpc_flavor2name_bulk(sf, &bspec[1], sizeof(bspec) - 1);
strlcat(buf, bspec, bufsize);
}
return buf;
}
EXPORT_SYMBOL(sptlrpc_flavor2name);
char *sptlrpc_secflags2str(__u32 flags, char *buf, int bufsize)
{
buf[0] = '\0';
if (flags & PTLRPC_SEC_FL_REVERSE)
strlcat(buf, "reverse,", bufsize);
if (flags & PTLRPC_SEC_FL_ROOTONLY)
strlcat(buf, "rootonly,", bufsize);
if (flags & PTLRPC_SEC_FL_UDESC)
strlcat(buf, "udesc,", bufsize);
if (flags & PTLRPC_SEC_FL_BULK)
strlcat(buf, "bulk,", bufsize);
if (buf[0] == '\0')
strlcat(buf, "-,", bufsize);
return buf;
}
EXPORT_SYMBOL(sptlrpc_secflags2str);
/**************************************************
* client context APIs *
**************************************************/
static
struct ptlrpc_cli_ctx *get_my_ctx(struct ptlrpc_sec *sec)
{
struct vfs_cred vcred;
int create = 1, remove_dead = 1;
LASSERT(sec);
LASSERT(sec->ps_policy->sp_cops->lookup_ctx);
if (sec->ps_flvr.sf_flags & (PTLRPC_SEC_FL_REVERSE |
PTLRPC_SEC_FL_ROOTONLY)) {
vcred.vc_uid = 0;
vcred.vc_gid = 0;
if (sec->ps_flvr.sf_flags & PTLRPC_SEC_FL_REVERSE) {
create = 0;
remove_dead = 0;
}
} else {
vcred.vc_uid = from_kuid(&init_user_ns, current_uid());
vcred.vc_gid = from_kgid(&init_user_ns, current_gid());
}
return sec->ps_policy->sp_cops->lookup_ctx(sec, &vcred,
create, remove_dead);
}
struct ptlrpc_cli_ctx *sptlrpc_cli_ctx_get(struct ptlrpc_cli_ctx *ctx)
{
atomic_inc(&ctx->cc_refcount);
return ctx;
}
EXPORT_SYMBOL(sptlrpc_cli_ctx_get);
void sptlrpc_cli_ctx_put(struct ptlrpc_cli_ctx *ctx, int sync)
{
struct ptlrpc_sec *sec = ctx->cc_sec;
LASSERT(sec);
LASSERT_ATOMIC_POS(&ctx->cc_refcount);
if (!atomic_dec_and_test(&ctx->cc_refcount))
return;
sec->ps_policy->sp_cops->release_ctx(sec, ctx, sync);
}
EXPORT_SYMBOL(sptlrpc_cli_ctx_put);
/**
* Expire the client context immediately.
*
* \pre Caller must hold at least 1 reference on the \a ctx.
*/
void sptlrpc_cli_ctx_expire(struct ptlrpc_cli_ctx *ctx)
{
LASSERT(ctx->cc_ops->force_die);
ctx->cc_ops->force_die(ctx, 0);
}
EXPORT_SYMBOL(sptlrpc_cli_ctx_expire);
/**
* To wake up the threads who are waiting for this client context. Called
* after some status change happened on \a ctx.
*/
void sptlrpc_cli_ctx_wakeup(struct ptlrpc_cli_ctx *ctx)
{
struct ptlrpc_request *req, *next;
spin_lock(&ctx->cc_lock);
list_for_each_entry_safe(req, next, &ctx->cc_req_list,
rq_ctx_chain) {
list_del_init(&req->rq_ctx_chain);
ptlrpc_client_wake_req(req);
}
spin_unlock(&ctx->cc_lock);
}
EXPORT_SYMBOL(sptlrpc_cli_ctx_wakeup);
int sptlrpc_cli_ctx_display(struct ptlrpc_cli_ctx *ctx, char *buf, int bufsize)
{
LASSERT(ctx->cc_ops);
if (ctx->cc_ops->display == NULL)
return 0;
return ctx->cc_ops->display(ctx, buf, bufsize);
}
static int import_sec_check_expire(struct obd_import *imp)
{
int adapt = 0;
spin_lock(&imp->imp_lock);
if (imp->imp_sec_expire &&
imp->imp_sec_expire < get_seconds()) {
adapt = 1;
imp->imp_sec_expire = 0;
}
spin_unlock(&imp->imp_lock);
if (!adapt)
return 0;
CDEBUG(D_SEC, "found delayed sec adapt expired, do it now\n");
return sptlrpc_import_sec_adapt(imp, NULL, NULL);
}
static int import_sec_validate_get(struct obd_import *imp,
struct ptlrpc_sec **sec)
{
int rc;
if (unlikely(imp->imp_sec_expire)) {
rc = import_sec_check_expire(imp);
if (rc)
return rc;
}
*sec = sptlrpc_import_sec_ref(imp);
if (*sec == NULL) {
CERROR("import %p (%s) with no sec\n",
imp, ptlrpc_import_state_name(imp->imp_state));
return -EACCES;
}
if (unlikely((*sec)->ps_dying)) {
CERROR("attempt to use dying sec %p\n", sec);
sptlrpc_sec_put(*sec);
return -EACCES;
}
return 0;
}
/**
* Given a \a req, find or allocate a appropriate context for it.
* \pre req->rq_cli_ctx == NULL.
*
* \retval 0 succeed, and req->rq_cli_ctx is set.
* \retval -ev error number, and req->rq_cli_ctx == NULL.
*/
int sptlrpc_req_get_ctx(struct ptlrpc_request *req)
{
struct obd_import *imp = req->rq_import;
struct ptlrpc_sec *sec;
int rc;
LASSERT(!req->rq_cli_ctx);
LASSERT(imp);
rc = import_sec_validate_get(imp, &sec);
if (rc)
return rc;
req->rq_cli_ctx = get_my_ctx(sec);
sptlrpc_sec_put(sec);
if (!req->rq_cli_ctx) {
CERROR("req %p: fail to get context\n", req);
return -ENOMEM;
}
return 0;
}
/**
* Drop the context for \a req.
* \pre req->rq_cli_ctx != NULL.
* \post req->rq_cli_ctx == NULL.
*
* If \a sync == 0, this function should return quickly without sleep;
* otherwise it might trigger and wait for the whole process of sending
* an context-destroying rpc to server.
*/
void sptlrpc_req_put_ctx(struct ptlrpc_request *req, int sync)
{
LASSERT(req);
LASSERT(req->rq_cli_ctx);
/* request might be asked to release earlier while still
* in the context waiting list.
*/
if (!list_empty(&req->rq_ctx_chain)) {
spin_lock(&req->rq_cli_ctx->cc_lock);
list_del_init(&req->rq_ctx_chain);
spin_unlock(&req->rq_cli_ctx->cc_lock);
}
sptlrpc_cli_ctx_put(req->rq_cli_ctx, sync);
req->rq_cli_ctx = NULL;
}
static
int sptlrpc_req_ctx_switch(struct ptlrpc_request *req,
struct ptlrpc_cli_ctx *oldctx,
struct ptlrpc_cli_ctx *newctx)
{
struct sptlrpc_flavor old_flvr;
char *reqmsg = NULL; /* to workaround old gcc */
int reqmsg_size;
int rc = 0;
LASSERT(req->rq_reqmsg);
LASSERT(req->rq_reqlen);
LASSERT(req->rq_replen);
CDEBUG(D_SEC, "req %p: switch ctx %p(%u->%s) -> %p(%u->%s), switch sec %p(%s) -> %p(%s)\n",
req,
oldctx, oldctx->cc_vcred.vc_uid, sec2target_str(oldctx->cc_sec),
newctx, newctx->cc_vcred.vc_uid, sec2target_str(newctx->cc_sec),
oldctx->cc_sec, oldctx->cc_sec->ps_policy->sp_name,
newctx->cc_sec, newctx->cc_sec->ps_policy->sp_name);
/* save flavor */
old_flvr = req->rq_flvr;
/* save request message */
reqmsg_size = req->rq_reqlen;
if (reqmsg_size != 0) {
OBD_ALLOC_LARGE(reqmsg, reqmsg_size);
if (reqmsg == NULL)
return -ENOMEM;
memcpy(reqmsg, req->rq_reqmsg, reqmsg_size);
}
/* release old req/rep buf */
req->rq_cli_ctx = oldctx;
sptlrpc_cli_free_reqbuf(req);
sptlrpc_cli_free_repbuf(req);
req->rq_cli_ctx = newctx;
/* recalculate the flavor */
sptlrpc_req_set_flavor(req, 0);
/* alloc new request buffer
* we don't need to alloc reply buffer here, leave it to the
* rest procedure of ptlrpc */
if (reqmsg_size != 0) {
rc = sptlrpc_cli_alloc_reqbuf(req, reqmsg_size);
if (!rc) {
LASSERT(req->rq_reqmsg);
memcpy(req->rq_reqmsg, reqmsg, reqmsg_size);
} else {
CWARN("failed to alloc reqbuf: %d\n", rc);
req->rq_flvr = old_flvr;
}
OBD_FREE_LARGE(reqmsg, reqmsg_size);
}
return rc;
}
/**
* If current context of \a req is dead somehow, e.g. we just switched flavor
* thus marked original contexts dead, we'll find a new context for it. if
* no switch is needed, \a req will end up with the same context.
*
* \note a request must have a context, to keep other parts of code happy.
* In any case of failure during the switching, we must restore the old one.
*/
int sptlrpc_req_replace_dead_ctx(struct ptlrpc_request *req)
{
struct ptlrpc_cli_ctx *oldctx = req->rq_cli_ctx;
struct ptlrpc_cli_ctx *newctx;
int rc;
LASSERT(oldctx);
sptlrpc_cli_ctx_get(oldctx);
sptlrpc_req_put_ctx(req, 0);
rc = sptlrpc_req_get_ctx(req);
if (unlikely(rc)) {
LASSERT(!req->rq_cli_ctx);
/* restore old ctx */
req->rq_cli_ctx = oldctx;
return rc;
}
newctx = req->rq_cli_ctx;
LASSERT(newctx);
if (unlikely(newctx == oldctx &&
test_bit(PTLRPC_CTX_DEAD_BIT, &oldctx->cc_flags))) {
/*
* still get the old dead ctx, usually means system too busy
*/
CDEBUG(D_SEC,
"ctx (%p, fl %lx) doesn't switch, relax a little bit\n",
newctx, newctx->cc_flags);
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(HZ);
} else {
/*
* it's possible newctx == oldctx if we're switching
* subflavor with the same sec.
*/
rc = sptlrpc_req_ctx_switch(req, oldctx, newctx);
if (rc) {
/* restore old ctx */
sptlrpc_req_put_ctx(req, 0);
req->rq_cli_ctx = oldctx;
return rc;
}
LASSERT(req->rq_cli_ctx == newctx);
}
sptlrpc_cli_ctx_put(oldctx, 1);
return 0;
}
EXPORT_SYMBOL(sptlrpc_req_replace_dead_ctx);
static
int ctx_check_refresh(struct ptlrpc_cli_ctx *ctx)
{
if (cli_ctx_is_refreshed(ctx))
return 1;
return 0;
}
static
int ctx_refresh_timeout(void *data)
{
struct ptlrpc_request *req = data;
int rc;
/* conn_cnt is needed in expire_one_request */
lustre_msg_set_conn_cnt(req->rq_reqmsg, req->rq_import->imp_conn_cnt);
rc = ptlrpc_expire_one_request(req, 1);
/* if we started recovery, we should mark this ctx dead; otherwise
* in case of lgssd died nobody would retire this ctx, following
* connecting will still find the same ctx thus cause deadlock.
* there's an assumption that expire time of the request should be
* later than the context refresh expire time.
*/
if (rc == 0)
req->rq_cli_ctx->cc_ops->force_die(req->rq_cli_ctx, 0);
return rc;
}
static
void ctx_refresh_interrupt(void *data)
{
struct ptlrpc_request *req = data;
spin_lock(&req->rq_lock);
req->rq_intr = 1;
spin_unlock(&req->rq_lock);
}
static
void req_off_ctx_list(struct ptlrpc_request *req, struct ptlrpc_cli_ctx *ctx)
{
spin_lock(&ctx->cc_lock);
if (!list_empty(&req->rq_ctx_chain))
list_del_init(&req->rq_ctx_chain);
spin_unlock(&ctx->cc_lock);
}
/**
* To refresh the context of \req, if it's not up-to-date.
* \param timeout
* - < 0: don't wait
* - = 0: wait until success or fatal error occur
* - > 0: timeout value (in seconds)
*
* The status of the context could be subject to be changed by other threads
* at any time. We allow this race, but once we return with 0, the caller will
* suppose it's uptodated and keep using it until the owning rpc is done.
*
* \retval 0 only if the context is uptodated.
* \retval -ev error number.
*/
int sptlrpc_req_refresh_ctx(struct ptlrpc_request *req, long timeout)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec *sec;
struct l_wait_info lwi;
int rc;
LASSERT(ctx);
if (req->rq_ctx_init || req->rq_ctx_fini)
return 0;
/*
* during the process a request's context might change type even
* (e.g. from gss ctx to null ctx), so each loop we need to re-check
* everything
*/
again:
rc = import_sec_validate_get(req->rq_import, &sec);
if (rc)
return rc;
if (sec->ps_flvr.sf_rpc != req->rq_flvr.sf_rpc) {
CDEBUG(D_SEC, "req %p: flavor has changed %x -> %x\n",
req, req->rq_flvr.sf_rpc, sec->ps_flvr.sf_rpc);
req_off_ctx_list(req, ctx);
sptlrpc_req_replace_dead_ctx(req);
ctx = req->rq_cli_ctx;
}
sptlrpc_sec_put(sec);
if (cli_ctx_is_eternal(ctx))
return 0;
if (unlikely(test_bit(PTLRPC_CTX_NEW_BIT, &ctx->cc_flags))) {
LASSERT(ctx->cc_ops->refresh);
ctx->cc_ops->refresh(ctx);
}
LASSERT(test_bit(PTLRPC_CTX_NEW_BIT, &ctx->cc_flags) == 0);
LASSERT(ctx->cc_ops->validate);
if (ctx->cc_ops->validate(ctx) == 0) {
req_off_ctx_list(req, ctx);
return 0;
}
if (unlikely(test_bit(PTLRPC_CTX_ERROR_BIT, &ctx->cc_flags))) {
spin_lock(&req->rq_lock);
req->rq_err = 1;
spin_unlock(&req->rq_lock);
req_off_ctx_list(req, ctx);
return -EPERM;
}
/*
* There's a subtle issue for resending RPCs, suppose following
* situation:
* 1. the request was sent to server.
* 2. recovery was kicked start, after finished the request was
* marked as resent.
* 3. resend the request.
* 4. old reply from server received, we accept and verify the reply.
* this has to be success, otherwise the error will be aware
* by application.
* 5. new reply from server received, dropped by LNet.
*
* Note the xid of old & new request is the same. We can't simply
* change xid for the resent request because the server replies on
* it for reply reconstruction.
*
* Commonly the original context should be uptodate because we
* have a expiry nice time; server will keep its context because
* we at least hold a ref of old context which prevent context
* destroying RPC being sent. So server still can accept the request
* and finish the RPC. But if that's not the case:
* 1. If server side context has been trimmed, a NO_CONTEXT will
* be returned, gss_cli_ctx_verify/unseal will switch to new
* context by force.
* 2. Current context never be refreshed, then we are fine: we
* never really send request with old context before.
*/
if (test_bit(PTLRPC_CTX_UPTODATE_BIT, &ctx->cc_flags) &&
unlikely(req->rq_reqmsg) &&
lustre_msg_get_flags(req->rq_reqmsg) & MSG_RESENT) {
req_off_ctx_list(req, ctx);
return 0;
}
if (unlikely(test_bit(PTLRPC_CTX_DEAD_BIT, &ctx->cc_flags))) {
req_off_ctx_list(req, ctx);
/*
* don't switch ctx if import was deactivated
*/
if (req->rq_import->imp_deactive) {
spin_lock(&req->rq_lock);
req->rq_err = 1;
spin_unlock(&req->rq_lock);
return -EINTR;
}
rc = sptlrpc_req_replace_dead_ctx(req);
if (rc) {
LASSERT(ctx == req->rq_cli_ctx);
CERROR("req %p: failed to replace dead ctx %p: %d\n",
req, ctx, rc);
spin_lock(&req->rq_lock);
req->rq_err = 1;
spin_unlock(&req->rq_lock);
return rc;
}
ctx = req->rq_cli_ctx;
goto again;
}
/*
* Now we're sure this context is during upcall, add myself into
* waiting list
*/
spin_lock(&ctx->cc_lock);
if (list_empty(&req->rq_ctx_chain))
list_add(&req->rq_ctx_chain, &ctx->cc_req_list);
spin_unlock(&ctx->cc_lock);
if (timeout < 0)
return -EWOULDBLOCK;
/* Clear any flags that may be present from previous sends */
LASSERT(req->rq_receiving_reply == 0);
spin_lock(&req->rq_lock);
req->rq_err = 0;
req->rq_timedout = 0;
req->rq_resend = 0;
req->rq_restart = 0;
spin_unlock(&req->rq_lock);
lwi = LWI_TIMEOUT_INTR(timeout * HZ, ctx_refresh_timeout,
ctx_refresh_interrupt, req);
rc = l_wait_event(req->rq_reply_waitq, ctx_check_refresh(ctx), &lwi);
/*
* following cases could lead us here:
* - successfully refreshed;
* - interrupted;
* - timedout, and we don't want recover from the failure;
* - timedout, and waked up upon recovery finished;
* - someone else mark this ctx dead by force;
* - someone invalidate the req and call ptlrpc_client_wake_req(),
* e.g. ptlrpc_abort_inflight();
*/
if (!cli_ctx_is_refreshed(ctx)) {
/* timed out or interrupted */
req_off_ctx_list(req, ctx);
LASSERT(rc != 0);
return rc;
}
goto again;
}
/**
* Initialize flavor settings for \a req, according to \a opcode.
*
* \note this could be called in two situations:
* - new request from ptlrpc_pre_req(), with proper @opcode
* - old request which changed ctx in the middle, with @opcode == 0
*/
void sptlrpc_req_set_flavor(struct ptlrpc_request *req, int opcode)
{
struct ptlrpc_sec *sec;
LASSERT(req->rq_import);
LASSERT(req->rq_cli_ctx);
LASSERT(req->rq_cli_ctx->cc_sec);
LASSERT(req->rq_bulk_read == 0 || req->rq_bulk_write == 0);
/* special security flags according to opcode */
switch (opcode) {
case OST_READ:
case MDS_READPAGE:
case MGS_CONFIG_READ:
case OBD_IDX_READ:
req->rq_bulk_read = 1;
break;
case OST_WRITE:
case MDS_WRITEPAGE:
req->rq_bulk_write = 1;
break;
case SEC_CTX_INIT:
req->rq_ctx_init = 1;
break;
case SEC_CTX_FINI:
req->rq_ctx_fini = 1;
break;
case 0:
/* init/fini rpc won't be resend, so can't be here */
LASSERT(req->rq_ctx_init == 0);
LASSERT(req->rq_ctx_fini == 0);
/* cleanup flags, which should be recalculated */
req->rq_pack_udesc = 0;
req->rq_pack_bulk = 0;
break;
}
sec = req->rq_cli_ctx->cc_sec;
spin_lock(&sec->ps_lock);
req->rq_flvr = sec->ps_flvr;
spin_unlock(&sec->ps_lock);
/* force SVC_NULL for context initiation rpc, SVC_INTG for context
* destruction rpc */
if (unlikely(req->rq_ctx_init))
flvr_set_svc(&req->rq_flvr.sf_rpc, SPTLRPC_SVC_NULL);
else if (unlikely(req->rq_ctx_fini))
flvr_set_svc(&req->rq_flvr.sf_rpc, SPTLRPC_SVC_INTG);
/* user descriptor flag, null security can't do it anyway */
if ((sec->ps_flvr.sf_flags & PTLRPC_SEC_FL_UDESC) &&
(req->rq_flvr.sf_rpc != SPTLRPC_FLVR_NULL))
req->rq_pack_udesc = 1;
/* bulk security flag */
if ((req->rq_bulk_read || req->rq_bulk_write) &&
sptlrpc_flavor_has_bulk(&req->rq_flvr))
req->rq_pack_bulk = 1;
}
void sptlrpc_request_out_callback(struct ptlrpc_request *req)
{
if (SPTLRPC_FLVR_SVC(req->rq_flvr.sf_rpc) != SPTLRPC_SVC_PRIV)
return;
LASSERT(req->rq_clrbuf);
if (req->rq_pool || !req->rq_reqbuf)
return;
OBD_FREE(req->rq_reqbuf, req->rq_reqbuf_len);
req->rq_reqbuf = NULL;
req->rq_reqbuf_len = 0;
}
/**
* Given an import \a imp, check whether current user has a valid context
* or not. We may create a new context and try to refresh it, and try
* repeatedly try in case of non-fatal errors. Return 0 means success.
*/
int sptlrpc_import_check_ctx(struct obd_import *imp)
{
struct ptlrpc_sec *sec;
struct ptlrpc_cli_ctx *ctx;
struct ptlrpc_request *req = NULL;
int rc;
might_sleep();
sec = sptlrpc_import_sec_ref(imp);
ctx = get_my_ctx(sec);
sptlrpc_sec_put(sec);
if (!ctx)
return -ENOMEM;
if (cli_ctx_is_eternal(ctx) ||
ctx->cc_ops->validate(ctx) == 0) {
sptlrpc_cli_ctx_put(ctx, 1);
return 0;
}
if (cli_ctx_is_error(ctx)) {
sptlrpc_cli_ctx_put(ctx, 1);
return -EACCES;
}
req = ptlrpc_request_cache_alloc(GFP_NOFS);
if (!req)
return -ENOMEM;
spin_lock_init(&req->rq_lock);
atomic_set(&req->rq_refcount, 10000);
INIT_LIST_HEAD(&req->rq_ctx_chain);
init_waitqueue_head(&req->rq_reply_waitq);
init_waitqueue_head(&req->rq_set_waitq);
req->rq_import = imp;
req->rq_flvr = sec->ps_flvr;
req->rq_cli_ctx = ctx;
rc = sptlrpc_req_refresh_ctx(req, 0);
LASSERT(list_empty(&req->rq_ctx_chain));
sptlrpc_cli_ctx_put(req->rq_cli_ctx, 1);
ptlrpc_request_cache_free(req);
return rc;
}
/**
* Used by ptlrpc client, to perform the pre-defined security transformation
* upon the request message of \a req. After this function called,
* req->rq_reqmsg is still accessible as clear text.
*/
int sptlrpc_cli_wrap_request(struct ptlrpc_request *req)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
int rc = 0;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(req->rq_reqbuf || req->rq_clrbuf);
/* we wrap bulk request here because now we can be sure
* the context is uptodate.
*/
if (req->rq_bulk) {
rc = sptlrpc_cli_wrap_bulk(req, req->rq_bulk);
if (rc)
return rc;
}
switch (SPTLRPC_FLVR_SVC(req->rq_flvr.sf_rpc)) {
case SPTLRPC_SVC_NULL:
case SPTLRPC_SVC_AUTH:
case SPTLRPC_SVC_INTG:
LASSERT(ctx->cc_ops->sign);
rc = ctx->cc_ops->sign(ctx, req);
break;
case SPTLRPC_SVC_PRIV:
LASSERT(ctx->cc_ops->seal);
rc = ctx->cc_ops->seal(ctx, req);
break;
default:
LBUG();
}
if (rc == 0) {
LASSERT(req->rq_reqdata_len);
LASSERT(req->rq_reqdata_len % 8 == 0);
LASSERT(req->rq_reqdata_len <= req->rq_reqbuf_len);
}
return rc;
}
static int do_cli_unwrap_reply(struct ptlrpc_request *req)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
int rc;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(req->rq_repbuf);
LASSERT(req->rq_repdata);
LASSERT(req->rq_repmsg == NULL);
req->rq_rep_swab_mask = 0;
rc = __lustre_unpack_msg(req->rq_repdata, req->rq_repdata_len);
switch (rc) {
case 1:
lustre_set_rep_swabbed(req, MSG_PTLRPC_HEADER_OFF);
case 0:
break;
default:
CERROR("failed unpack reply: x%llu\n", req->rq_xid);
return -EPROTO;
}
if (req->rq_repdata_len < sizeof(struct lustre_msg)) {
CERROR("replied data length %d too small\n",
req->rq_repdata_len);
return -EPROTO;
}
if (SPTLRPC_FLVR_POLICY(req->rq_repdata->lm_secflvr) !=
SPTLRPC_FLVR_POLICY(req->rq_flvr.sf_rpc)) {
CERROR("reply policy %u doesn't match request policy %u\n",
SPTLRPC_FLVR_POLICY(req->rq_repdata->lm_secflvr),
SPTLRPC_FLVR_POLICY(req->rq_flvr.sf_rpc));
return -EPROTO;
}
switch (SPTLRPC_FLVR_SVC(req->rq_flvr.sf_rpc)) {
case SPTLRPC_SVC_NULL:
case SPTLRPC_SVC_AUTH:
case SPTLRPC_SVC_INTG:
LASSERT(ctx->cc_ops->verify);
rc = ctx->cc_ops->verify(ctx, req);
break;
case SPTLRPC_SVC_PRIV:
LASSERT(ctx->cc_ops->unseal);
rc = ctx->cc_ops->unseal(ctx, req);
break;
default:
LBUG();
}
LASSERT(rc || req->rq_repmsg || req->rq_resend);
if (SPTLRPC_FLVR_POLICY(req->rq_flvr.sf_rpc) != SPTLRPC_POLICY_NULL &&
!req->rq_ctx_init)
req->rq_rep_swab_mask = 0;
return rc;
}
/**
* Used by ptlrpc client, to perform security transformation upon the reply
* message of \a req. After return successfully, req->rq_repmsg points to
* the reply message in clear text.
*
* \pre the reply buffer should have been un-posted from LNet, so nothing is
* going to change.
*/
int sptlrpc_cli_unwrap_reply(struct ptlrpc_request *req)
{
LASSERT(req->rq_repbuf);
LASSERT(req->rq_repdata == NULL);
LASSERT(req->rq_repmsg == NULL);
LASSERT(req->rq_reply_off + req->rq_nob_received <= req->rq_repbuf_len);
if (req->rq_reply_off == 0 &&
(lustre_msghdr_get_flags(req->rq_reqmsg) & MSGHDR_AT_SUPPORT)) {
CERROR("real reply with offset 0\n");
return -EPROTO;
}
if (req->rq_reply_off % 8 != 0) {
CERROR("reply at odd offset %u\n", req->rq_reply_off);
return -EPROTO;
}
req->rq_repdata = (struct lustre_msg *)
(req->rq_repbuf + req->rq_reply_off);
req->rq_repdata_len = req->rq_nob_received;
return do_cli_unwrap_reply(req);
}
/**
* Used by ptlrpc client, to perform security transformation upon the early
* reply message of \a req. We expect the rq_reply_off is 0, and
* rq_nob_received is the early reply size.
*
* Because the receive buffer might be still posted, the reply data might be
* changed at any time, no matter we're holding rq_lock or not. For this reason
* we allocate a separate ptlrpc_request and reply buffer for early reply
* processing.
*
* \retval 0 success, \a req_ret is filled with a duplicated ptlrpc_request.
* Later the caller must call sptlrpc_cli_finish_early_reply() on the returned
* \a *req_ret to release it.
* \retval -ev error number, and \a req_ret will not be set.
*/
int sptlrpc_cli_unwrap_early_reply(struct ptlrpc_request *req,
struct ptlrpc_request **req_ret)
{
struct ptlrpc_request *early_req;
char *early_buf;
int early_bufsz, early_size;
int rc;
early_req = ptlrpc_request_cache_alloc(GFP_NOFS);
if (early_req == NULL)
return -ENOMEM;
early_size = req->rq_nob_received;
early_bufsz = size_roundup_power2(early_size);
OBD_ALLOC_LARGE(early_buf, early_bufsz);
if (early_buf == NULL) {
rc = -ENOMEM;
goto err_req;
}
/* sanity checkings and copy data out, do it inside spinlock */
spin_lock(&req->rq_lock);
if (req->rq_replied) {
spin_unlock(&req->rq_lock);
rc = -EALREADY;
goto err_buf;
}
LASSERT(req->rq_repbuf);
LASSERT(req->rq_repdata == NULL);
LASSERT(req->rq_repmsg == NULL);
if (req->rq_reply_off != 0) {
CERROR("early reply with offset %u\n", req->rq_reply_off);
spin_unlock(&req->rq_lock);
rc = -EPROTO;
goto err_buf;
}
if (req->rq_nob_received != early_size) {
/* even another early arrived the size should be the same */
CERROR("data size has changed from %u to %u\n",
early_size, req->rq_nob_received);
spin_unlock(&req->rq_lock);
rc = -EINVAL;
goto err_buf;
}
if (req->rq_nob_received < sizeof(struct lustre_msg)) {
CERROR("early reply length %d too small\n",
req->rq_nob_received);
spin_unlock(&req->rq_lock);
rc = -EALREADY;
goto err_buf;
}
memcpy(early_buf, req->rq_repbuf, early_size);
spin_unlock(&req->rq_lock);
spin_lock_init(&early_req->rq_lock);
early_req->rq_cli_ctx = sptlrpc_cli_ctx_get(req->rq_cli_ctx);
early_req->rq_flvr = req->rq_flvr;
early_req->rq_repbuf = early_buf;
early_req->rq_repbuf_len = early_bufsz;
early_req->rq_repdata = (struct lustre_msg *) early_buf;
early_req->rq_repdata_len = early_size;
early_req->rq_early = 1;
early_req->rq_reqmsg = req->rq_reqmsg;
rc = do_cli_unwrap_reply(early_req);
if (rc) {
DEBUG_REQ(D_ADAPTTO, early_req,
"error %d unwrap early reply", rc);
goto err_ctx;
}
LASSERT(early_req->rq_repmsg);
*req_ret = early_req;
return 0;
err_ctx:
sptlrpc_cli_ctx_put(early_req->rq_cli_ctx, 1);
err_buf:
OBD_FREE_LARGE(early_buf, early_bufsz);
err_req:
ptlrpc_request_cache_free(early_req);
return rc;
}
/**
* Used by ptlrpc client, to release a processed early reply \a early_req.
*
* \pre \a early_req was obtained from calling sptlrpc_cli_unwrap_early_reply().
*/
void sptlrpc_cli_finish_early_reply(struct ptlrpc_request *early_req)
{
LASSERT(early_req->rq_repbuf);
LASSERT(early_req->rq_repdata);
LASSERT(early_req->rq_repmsg);
sptlrpc_cli_ctx_put(early_req->rq_cli_ctx, 1);
OBD_FREE_LARGE(early_req->rq_repbuf, early_req->rq_repbuf_len);
ptlrpc_request_cache_free(early_req);
}
/**************************************************
* sec ID *
**************************************************/
/*
* "fixed" sec (e.g. null) use sec_id < 0
*/
static atomic_t sptlrpc_sec_id = ATOMIC_INIT(1);
int sptlrpc_get_next_secid(void)
{
return atomic_inc_return(&sptlrpc_sec_id);
}
EXPORT_SYMBOL(sptlrpc_get_next_secid);
/**************************************************
* client side high-level security APIs *
**************************************************/
static int sec_cop_flush_ctx_cache(struct ptlrpc_sec *sec, uid_t uid,
int grace, int force)
{
struct ptlrpc_sec_policy *policy = sec->ps_policy;
LASSERT(policy->sp_cops);
LASSERT(policy->sp_cops->flush_ctx_cache);
return policy->sp_cops->flush_ctx_cache(sec, uid, grace, force);
}
static void sec_cop_destroy_sec(struct ptlrpc_sec *sec)
{
struct ptlrpc_sec_policy *policy = sec->ps_policy;
LASSERT_ATOMIC_ZERO(&sec->ps_refcount);
LASSERT_ATOMIC_ZERO(&sec->ps_nctx);
LASSERT(policy->sp_cops->destroy_sec);
CDEBUG(D_SEC, "%s@%p: being destroyed\n", sec->ps_policy->sp_name, sec);
policy->sp_cops->destroy_sec(sec);
sptlrpc_policy_put(policy);
}
void sptlrpc_sec_destroy(struct ptlrpc_sec *sec)
{
sec_cop_destroy_sec(sec);
}
EXPORT_SYMBOL(sptlrpc_sec_destroy);
static void sptlrpc_sec_kill(struct ptlrpc_sec *sec)
{
LASSERT_ATOMIC_POS(&sec->ps_refcount);
if (sec->ps_policy->sp_cops->kill_sec) {
sec->ps_policy->sp_cops->kill_sec(sec);
sec_cop_flush_ctx_cache(sec, -1, 1, 1);
}
}
struct ptlrpc_sec *sptlrpc_sec_get(struct ptlrpc_sec *sec)
{
if (sec)
atomic_inc(&sec->ps_refcount);
return sec;
}
EXPORT_SYMBOL(sptlrpc_sec_get);
void sptlrpc_sec_put(struct ptlrpc_sec *sec)
{
if (sec) {
LASSERT_ATOMIC_POS(&sec->ps_refcount);
if (atomic_dec_and_test(&sec->ps_refcount)) {
sptlrpc_gc_del_sec(sec);
sec_cop_destroy_sec(sec);
}
}
}
EXPORT_SYMBOL(sptlrpc_sec_put);
/*
* policy module is responsible for taking reference of import
*/
static
struct ptlrpc_sec *sptlrpc_sec_create(struct obd_import *imp,
struct ptlrpc_svc_ctx *svc_ctx,
struct sptlrpc_flavor *sf,
enum lustre_sec_part sp)
{
struct ptlrpc_sec_policy *policy;
struct ptlrpc_sec *sec;
char str[32];
if (svc_ctx) {
LASSERT(imp->imp_dlm_fake == 1);
CDEBUG(D_SEC, "%s %s: reverse sec using flavor %s\n",
imp->imp_obd->obd_type->typ_name,
imp->imp_obd->obd_name,
sptlrpc_flavor2name(sf, str, sizeof(str)));
policy = sptlrpc_policy_get(svc_ctx->sc_policy);
sf->sf_flags |= PTLRPC_SEC_FL_REVERSE | PTLRPC_SEC_FL_ROOTONLY;
} else {
LASSERT(imp->imp_dlm_fake == 0);
CDEBUG(D_SEC, "%s %s: select security flavor %s\n",
imp->imp_obd->obd_type->typ_name,
imp->imp_obd->obd_name,
sptlrpc_flavor2name(sf, str, sizeof(str)));
policy = sptlrpc_wireflavor2policy(sf->sf_rpc);
if (!policy) {
CERROR("invalid flavor 0x%x\n", sf->sf_rpc);
return NULL;
}
}
sec = policy->sp_cops->create_sec(imp, svc_ctx, sf);
if (sec) {
atomic_inc(&sec->ps_refcount);
sec->ps_part = sp;
if (sec->ps_gc_interval && policy->sp_cops->gc_ctx)
sptlrpc_gc_add_sec(sec);
} else {
sptlrpc_policy_put(policy);
}
return sec;
}
struct ptlrpc_sec *sptlrpc_import_sec_ref(struct obd_import *imp)
{
struct ptlrpc_sec *sec;
spin_lock(&imp->imp_lock);
sec = sptlrpc_sec_get(imp->imp_sec);
spin_unlock(&imp->imp_lock);
return sec;
}
EXPORT_SYMBOL(sptlrpc_import_sec_ref);
static void sptlrpc_import_sec_install(struct obd_import *imp,
struct ptlrpc_sec *sec)
{
struct ptlrpc_sec *old_sec;
LASSERT_ATOMIC_POS(&sec->ps_refcount);
spin_lock(&imp->imp_lock);
old_sec = imp->imp_sec;
imp->imp_sec = sec;
spin_unlock(&imp->imp_lock);
if (old_sec) {
sptlrpc_sec_kill(old_sec);
/* balance the ref taken by this import */
sptlrpc_sec_put(old_sec);
}
}
static inline
int flavor_equal(struct sptlrpc_flavor *sf1, struct sptlrpc_flavor *sf2)
{
return (memcmp(sf1, sf2, sizeof(*sf1)) == 0);
}
static inline
void flavor_copy(struct sptlrpc_flavor *dst, struct sptlrpc_flavor *src)
{
*dst = *src;
}
static void sptlrpc_import_sec_adapt_inplace(struct obd_import *imp,
struct ptlrpc_sec *sec,
struct sptlrpc_flavor *sf)
{
char str1[32], str2[32];
if (sec->ps_flvr.sf_flags != sf->sf_flags)
CDEBUG(D_SEC, "changing sec flags: %s -> %s\n",
sptlrpc_secflags2str(sec->ps_flvr.sf_flags,
str1, sizeof(str1)),
sptlrpc_secflags2str(sf->sf_flags,
str2, sizeof(str2)));
spin_lock(&sec->ps_lock);
flavor_copy(&sec->ps_flvr, sf);
spin_unlock(&sec->ps_lock);
}
/**
* To get an appropriate ptlrpc_sec for the \a imp, according to the current
* configuration. Upon called, imp->imp_sec may or may not be NULL.
*
* - regular import: \a svc_ctx should be NULL and \a flvr is ignored;
* - reverse import: \a svc_ctx and \a flvr are obtained from incoming request.
*/
int sptlrpc_import_sec_adapt(struct obd_import *imp,
struct ptlrpc_svc_ctx *svc_ctx,
struct sptlrpc_flavor *flvr)
{
struct ptlrpc_connection *conn;
struct sptlrpc_flavor sf;
struct ptlrpc_sec *sec, *newsec;
enum lustre_sec_part sp;
char str[24];
int rc = 0;
might_sleep();
if (imp == NULL)
return 0;
conn = imp->imp_connection;
if (svc_ctx == NULL) {
struct client_obd *cliobd = &imp->imp_obd->u.cli;
/*
* normal import, determine flavor from rule set, except
* for mgc the flavor is predetermined.
*/
if (cliobd->cl_sp_me == LUSTRE_SP_MGC)
sf = cliobd->cl_flvr_mgc;
else
sptlrpc_conf_choose_flavor(cliobd->cl_sp_me,
cliobd->cl_sp_to,
&cliobd->cl_target_uuid,
conn->c_self, &sf);
sp = imp->imp_obd->u.cli.cl_sp_me;
} else {
/* reverse import, determine flavor from incoming request */
sf = *flvr;
if (sf.sf_rpc != SPTLRPC_FLVR_NULL)
sf.sf_flags = PTLRPC_SEC_FL_REVERSE |
PTLRPC_SEC_FL_ROOTONLY;
sp = sptlrpc_target_sec_part(imp->imp_obd);
}
sec = sptlrpc_import_sec_ref(imp);
if (sec) {
char str2[24];
if (flavor_equal(&sf, &sec->ps_flvr))
goto out;
CDEBUG(D_SEC, "import %s->%s: changing flavor %s -> %s\n",
imp->imp_obd->obd_name,
obd_uuid2str(&conn->c_remote_uuid),
sptlrpc_flavor2name(&sec->ps_flvr, str, sizeof(str)),
sptlrpc_flavor2name(&sf, str2, sizeof(str2)));
if (SPTLRPC_FLVR_POLICY(sf.sf_rpc) ==
SPTLRPC_FLVR_POLICY(sec->ps_flvr.sf_rpc) &&
SPTLRPC_FLVR_MECH(sf.sf_rpc) ==
SPTLRPC_FLVR_MECH(sec->ps_flvr.sf_rpc)) {
sptlrpc_import_sec_adapt_inplace(imp, sec, &sf);
goto out;
}
} else if (SPTLRPC_FLVR_BASE(sf.sf_rpc) !=
SPTLRPC_FLVR_BASE(SPTLRPC_FLVR_NULL)) {
CDEBUG(D_SEC, "import %s->%s netid %x: select flavor %s\n",
imp->imp_obd->obd_name,
obd_uuid2str(&conn->c_remote_uuid),
LNET_NIDNET(conn->c_self),
sptlrpc_flavor2name(&sf, str, sizeof(str)));
}
mutex_lock(&imp->imp_sec_mutex);
newsec = sptlrpc_sec_create(imp, svc_ctx, &sf, sp);
if (newsec) {
sptlrpc_import_sec_install(imp, newsec);
} else {
CERROR("import %s->%s: failed to create new sec\n",
imp->imp_obd->obd_name,
obd_uuid2str(&conn->c_remote_uuid));
rc = -EPERM;
}
mutex_unlock(&imp->imp_sec_mutex);
out:
sptlrpc_sec_put(sec);
return rc;
}
void sptlrpc_import_sec_put(struct obd_import *imp)
{
if (imp->imp_sec) {
sptlrpc_sec_kill(imp->imp_sec);
sptlrpc_sec_put(imp->imp_sec);
imp->imp_sec = NULL;
}
}
static void import_flush_ctx_common(struct obd_import *imp,
uid_t uid, int grace, int force)
{
struct ptlrpc_sec *sec;
if (imp == NULL)
return;
sec = sptlrpc_import_sec_ref(imp);
if (sec == NULL)
return;
sec_cop_flush_ctx_cache(sec, uid, grace, force);
sptlrpc_sec_put(sec);
}
void sptlrpc_import_flush_root_ctx(struct obd_import *imp)
{
/* it's important to use grace mode, see explain in
* sptlrpc_req_refresh_ctx() */
import_flush_ctx_common(imp, 0, 1, 1);
}
void sptlrpc_import_flush_my_ctx(struct obd_import *imp)
{
import_flush_ctx_common(imp, from_kuid(&init_user_ns, current_uid()),
1, 1);
}
EXPORT_SYMBOL(sptlrpc_import_flush_my_ctx);
void sptlrpc_import_flush_all_ctx(struct obd_import *imp)
{
import_flush_ctx_common(imp, -1, 1, 1);
}
EXPORT_SYMBOL(sptlrpc_import_flush_all_ctx);
/**
* Used by ptlrpc client to allocate request buffer of \a req. Upon return
* successfully, req->rq_reqmsg points to a buffer with size \a msgsize.
*/
int sptlrpc_cli_alloc_reqbuf(struct ptlrpc_request *req, int msgsize)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec_policy *policy;
int rc;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(ctx->cc_sec->ps_policy);
LASSERT(req->rq_reqmsg == NULL);
LASSERT_ATOMIC_POS(&ctx->cc_refcount);
policy = ctx->cc_sec->ps_policy;
rc = policy->sp_cops->alloc_reqbuf(ctx->cc_sec, req, msgsize);
if (!rc) {
LASSERT(req->rq_reqmsg);
LASSERT(req->rq_reqbuf || req->rq_clrbuf);
/* zeroing preallocated buffer */
if (req->rq_pool)
memset(req->rq_reqmsg, 0, msgsize);
}
return rc;
}
/**
* Used by ptlrpc client to free request buffer of \a req. After this
* req->rq_reqmsg is set to NULL and should not be accessed anymore.
*/
void sptlrpc_cli_free_reqbuf(struct ptlrpc_request *req)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec_policy *policy;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(ctx->cc_sec->ps_policy);
LASSERT_ATOMIC_POS(&ctx->cc_refcount);
if (req->rq_reqbuf == NULL && req->rq_clrbuf == NULL)
return;
policy = ctx->cc_sec->ps_policy;
policy->sp_cops->free_reqbuf(ctx->cc_sec, req);
req->rq_reqmsg = NULL;
}
/*
* NOTE caller must guarantee the buffer size is enough for the enlargement
*/
void _sptlrpc_enlarge_msg_inplace(struct lustre_msg *msg,
int segment, int newsize)
{
void *src, *dst;
int oldsize, oldmsg_size, movesize;
LASSERT(segment < msg->lm_bufcount);
LASSERT(msg->lm_buflens[segment] <= newsize);
if (msg->lm_buflens[segment] == newsize)
return;
/* nothing to do if we are enlarging the last segment */
if (segment == msg->lm_bufcount - 1) {
msg->lm_buflens[segment] = newsize;
return;
}
oldsize = msg->lm_buflens[segment];
src = lustre_msg_buf(msg, segment + 1, 0);
msg->lm_buflens[segment] = newsize;
dst = lustre_msg_buf(msg, segment + 1, 0);
msg->lm_buflens[segment] = oldsize;
/* move from segment + 1 to end segment */
LASSERT(msg->lm_magic == LUSTRE_MSG_MAGIC_V2);
oldmsg_size = lustre_msg_size_v2(msg->lm_bufcount, msg->lm_buflens);
movesize = oldmsg_size - ((unsigned long) src - (unsigned long) msg);
LASSERT(movesize >= 0);
if (movesize)
memmove(dst, src, movesize);
/* note we don't clear the ares where old data live, not secret */
/* finally set new segment size */
msg->lm_buflens[segment] = newsize;
}
EXPORT_SYMBOL(_sptlrpc_enlarge_msg_inplace);
/**
* Used by ptlrpc client to enlarge the \a segment of request message pointed
* by req->rq_reqmsg to size \a newsize, all previously filled-in data will be
* preserved after the enlargement. this must be called after original request
* buffer being allocated.
*
* \note after this be called, rq_reqmsg and rq_reqlen might have been changed,
* so caller should refresh its local pointers if needed.
*/
int sptlrpc_cli_enlarge_reqbuf(struct ptlrpc_request *req,
int segment, int newsize)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec_cops *cops;
struct lustre_msg *msg = req->rq_reqmsg;
LASSERT(ctx);
LASSERT(msg);
LASSERT(msg->lm_bufcount > segment);
LASSERT(msg->lm_buflens[segment] <= newsize);
if (msg->lm_buflens[segment] == newsize)
return 0;
cops = ctx->cc_sec->ps_policy->sp_cops;
LASSERT(cops->enlarge_reqbuf);
return cops->enlarge_reqbuf(ctx->cc_sec, req, segment, newsize);
}
EXPORT_SYMBOL(sptlrpc_cli_enlarge_reqbuf);
/**
* Used by ptlrpc client to allocate reply buffer of \a req.
*
* \note After this, req->rq_repmsg is still not accessible.
*/
int sptlrpc_cli_alloc_repbuf(struct ptlrpc_request *req, int msgsize)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec_policy *policy;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(ctx->cc_sec->ps_policy);
if (req->rq_repbuf)
return 0;
policy = ctx->cc_sec->ps_policy;
return policy->sp_cops->alloc_repbuf(ctx->cc_sec, req, msgsize);
}
/**
* Used by ptlrpc client to free reply buffer of \a req. After this
* req->rq_repmsg is set to NULL and should not be accessed anymore.
*/
void sptlrpc_cli_free_repbuf(struct ptlrpc_request *req)
{
struct ptlrpc_cli_ctx *ctx = req->rq_cli_ctx;
struct ptlrpc_sec_policy *policy;
LASSERT(ctx);
LASSERT(ctx->cc_sec);
LASSERT(ctx->cc_sec->ps_policy);
LASSERT_ATOMIC_POS(&ctx->cc_refcount);
if (req->rq_repbuf == NULL)
return;
LASSERT(req->rq_repbuf_len);
policy = ctx->cc_sec->ps_policy;
policy->sp_cops->free_repbuf(ctx->cc_sec, req);
req->rq_repmsg = NULL;
}
int sptlrpc_cli_install_rvs_ctx(struct obd_import *imp,
struct ptlrpc_cli_ctx *ctx)
{
struct ptlrpc_sec_policy *policy = ctx->cc_sec->ps_policy;
if (!policy->sp_cops->install_rctx)
return 0;
return policy->sp_cops->install_rctx(imp, ctx->cc_sec, ctx);
}
int sptlrpc_svc_install_rvs_ctx(struct obd_import *imp,
struct ptlrpc_svc_ctx *ctx)
{
struct ptlrpc_sec_policy *policy = ctx->sc_policy;
if (!policy->sp_sops->install_rctx)
return 0;
return policy->sp_sops->install_rctx(imp, ctx);
}
/****************************************
* server side security *
****************************************/
static int flavor_allowed(struct sptlrpc_flavor *exp,
struct ptlrpc_request *req)
{
struct sptlrpc_flavor *flvr = &req->rq_flvr;
if (exp->sf_rpc == SPTLRPC_FLVR_ANY || exp->sf_rpc == flvr->sf_rpc)
return 1;
if ((req->rq_ctx_init || req->rq_ctx_fini) &&
SPTLRPC_FLVR_POLICY(exp->sf_rpc) ==
SPTLRPC_FLVR_POLICY(flvr->sf_rpc) &&
SPTLRPC_FLVR_MECH(exp->sf_rpc) == SPTLRPC_FLVR_MECH(flvr->sf_rpc))
return 1;
return 0;
}
#define EXP_FLVR_UPDATE_EXPIRE (OBD_TIMEOUT_DEFAULT + 10)
/**
* Given an export \a exp, check whether the flavor of incoming \a req
* is allowed by the export \a exp. Main logic is about taking care of
* changing configurations. Return 0 means success.
*/
int sptlrpc_target_export_check(struct obd_export *exp,
struct ptlrpc_request *req)
{
struct sptlrpc_flavor flavor;
if (exp == NULL)
return 0;
/* client side export has no imp_reverse, skip
* FIXME maybe we should check flavor this as well??? */
if (exp->exp_imp_reverse == NULL)
return 0;
/* don't care about ctx fini rpc */
if (req->rq_ctx_fini)
return 0;
spin_lock(&exp->exp_lock);
/* if flavor just changed (exp->exp_flvr_changed != 0), we wait for
* the first req with the new flavor, then treat it as current flavor,
* adapt reverse sec according to it.
* note the first rpc with new flavor might not be with root ctx, in
* which case delay the sec_adapt by leaving exp_flvr_adapt == 1. */
if (unlikely(exp->exp_flvr_changed) &&
flavor_allowed(&exp->exp_flvr_old[1], req)) {
/* make the new flavor as "current", and old ones as
* about-to-expire */
CDEBUG(D_SEC, "exp %p: just changed: %x->%x\n", exp,
exp->exp_flvr.sf_rpc, exp->exp_flvr_old[1].sf_rpc);
flavor = exp->exp_flvr_old[1];
exp->exp_flvr_old[1] = exp->exp_flvr_old[0];
exp->exp_flvr_expire[1] = exp->exp_flvr_expire[0];
exp->exp_flvr_old[0] = exp->exp_flvr;
exp->exp_flvr_expire[0] = get_seconds() +
EXP_FLVR_UPDATE_EXPIRE;
exp->exp_flvr = flavor;
/* flavor change finished */
exp->exp_flvr_changed = 0;
LASSERT(exp->exp_flvr_adapt == 1);
/* if it's gss, we only interested in root ctx init */
if (req->rq_auth_gss &&
!(req->rq_ctx_init &&
(req->rq_auth_usr_root || req->rq_auth_usr_mdt ||
req->rq_auth_usr_ost))) {
spin_unlock(&exp->exp_lock);
CDEBUG(D_SEC, "is good but not root(%d:%d:%d:%d:%d)\n",
req->rq_auth_gss, req->rq_ctx_init,
req->rq_auth_usr_root, req->rq_auth_usr_mdt,
req->rq_auth_usr_ost);
return 0;
}
exp->exp_flvr_adapt = 0;
spin_unlock(&exp->exp_lock);
return sptlrpc_import_sec_adapt(exp->exp_imp_reverse,
req->rq_svc_ctx, &flavor);
}
/* if it equals to the current flavor, we accept it, but need to
* dealing with reverse sec/ctx */
if (likely(flavor_allowed(&exp->exp_flvr, req))) {
/* most cases should return here, we only interested in
* gss root ctx init */
if (!req->rq_auth_gss || !req->rq_ctx_init ||
(!req->rq_auth_usr_root && !req->rq_auth_usr_mdt &&
!req->rq_auth_usr_ost)) {
spin_unlock(&exp->exp_lock);
return 0;
}
/* if flavor just changed, we should not proceed, just leave
* it and current flavor will be discovered and replaced
* shortly, and let _this_ rpc pass through */
if (exp->exp_flvr_changed) {
LASSERT(exp->exp_flvr_adapt);
spin_unlock(&exp->exp_lock);
return 0;
}
if (exp->exp_flvr_adapt) {
exp->exp_flvr_adapt = 0;
CDEBUG(D_SEC, "exp %p (%x|%x|%x): do delayed adapt\n",
exp, exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_old[1].sf_rpc);
flavor = exp->exp_flvr;
spin_unlock(&exp->exp_lock);
return sptlrpc_import_sec_adapt(exp->exp_imp_reverse,
req->rq_svc_ctx,
&flavor);
} else {
CDEBUG(D_SEC, "exp %p (%x|%x|%x): is current flavor, install rvs ctx\n",
exp, exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_old[1].sf_rpc);
spin_unlock(&exp->exp_lock);
return sptlrpc_svc_install_rvs_ctx(exp->exp_imp_reverse,
req->rq_svc_ctx);
}
}
if (exp->exp_flvr_expire[0]) {
if (exp->exp_flvr_expire[0] >= get_seconds()) {
if (flavor_allowed(&exp->exp_flvr_old[0], req)) {
CDEBUG(D_SEC, "exp %p (%x|%x|%x): match the middle one (" CFS_DURATION_T ")\n", exp,
exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_old[1].sf_rpc,
exp->exp_flvr_expire[0] -
get_seconds());
spin_unlock(&exp->exp_lock);
return 0;
}
} else {
CDEBUG(D_SEC, "mark middle expired\n");
exp->exp_flvr_expire[0] = 0;
}
CDEBUG(D_SEC, "exp %p (%x|%x|%x): %x not match middle\n", exp,
exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc, exp->exp_flvr_old[1].sf_rpc,
req->rq_flvr.sf_rpc);
}
/* now it doesn't match the current flavor, the only chance we can
* accept it is match the old flavors which is not expired. */
if (exp->exp_flvr_changed == 0 && exp->exp_flvr_expire[1]) {
if (exp->exp_flvr_expire[1] >= get_seconds()) {
if (flavor_allowed(&exp->exp_flvr_old[1], req)) {
CDEBUG(D_SEC, "exp %p (%x|%x|%x): match the oldest one (" CFS_DURATION_T ")\n",
exp,
exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_old[1].sf_rpc,
exp->exp_flvr_expire[1] -
get_seconds());
spin_unlock(&exp->exp_lock);
return 0;
}
} else {
CDEBUG(D_SEC, "mark oldest expired\n");
exp->exp_flvr_expire[1] = 0;
}
CDEBUG(D_SEC, "exp %p (%x|%x|%x): %x not match found\n",
exp, exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc, exp->exp_flvr_old[1].sf_rpc,
req->rq_flvr.sf_rpc);
} else {
CDEBUG(D_SEC, "exp %p (%x|%x|%x): skip the last one\n",
exp, exp->exp_flvr.sf_rpc, exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_old[1].sf_rpc);
}
spin_unlock(&exp->exp_lock);
CWARN("exp %p(%s): req %p (%u|%u|%u|%u|%u|%u) with unauthorized flavor %x, expect %x|%x(%+ld)|%x(%+ld)\n",
exp, exp->exp_obd->obd_name,
req, req->rq_auth_gss, req->rq_ctx_init, req->rq_ctx_fini,
req->rq_auth_usr_root, req->rq_auth_usr_mdt, req->rq_auth_usr_ost,
req->rq_flvr.sf_rpc,
exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[0].sf_rpc,
exp->exp_flvr_expire[0] ?
(unsigned long) (exp->exp_flvr_expire[0] -
get_seconds()) : 0,
exp->exp_flvr_old[1].sf_rpc,
exp->exp_flvr_expire[1] ?
(unsigned long) (exp->exp_flvr_expire[1] -
get_seconds()) : 0);
return -EACCES;
}
EXPORT_SYMBOL(sptlrpc_target_export_check);
void sptlrpc_target_update_exp_flavor(struct obd_device *obd,
struct sptlrpc_rule_set *rset)
{
struct obd_export *exp;
struct sptlrpc_flavor new_flvr;
LASSERT(obd);
spin_lock(&obd->obd_dev_lock);
list_for_each_entry(exp, &obd->obd_exports, exp_obd_chain) {
if (exp->exp_connection == NULL)
continue;
/* note if this export had just been updated flavor
* (exp_flvr_changed == 1), this will override the
* previous one. */
spin_lock(&exp->exp_lock);
sptlrpc_target_choose_flavor(rset, exp->exp_sp_peer,
exp->exp_connection->c_peer.nid,
&new_flvr);
if (exp->exp_flvr_changed ||
!flavor_equal(&new_flvr, &exp->exp_flvr)) {
exp->exp_flvr_old[1] = new_flvr;
exp->exp_flvr_expire[1] = 0;
exp->exp_flvr_changed = 1;
exp->exp_flvr_adapt = 1;
CDEBUG(D_SEC, "exp %p (%s): updated flavor %x->%x\n",
exp, sptlrpc_part2name(exp->exp_sp_peer),
exp->exp_flvr.sf_rpc,
exp->exp_flvr_old[1].sf_rpc);
}
spin_unlock(&exp->exp_lock);
}
spin_unlock(&obd->obd_dev_lock);
}
EXPORT_SYMBOL(sptlrpc_target_update_exp_flavor);
static int sptlrpc_svc_check_from(struct ptlrpc_request *req, int svc_rc)
{
/* peer's claim is unreliable unless gss is being used */
if (!req->rq_auth_gss || svc_rc == SECSVC_DROP)
return svc_rc;
switch (req->rq_sp_from) {
case LUSTRE_SP_CLI:
if (req->rq_auth_usr_mdt || req->rq_auth_usr_ost) {
DEBUG_REQ(D_ERROR, req, "faked source CLI");
svc_rc = SECSVC_DROP;
}
break;
case LUSTRE_SP_MDT:
if (!req->rq_auth_usr_mdt) {
DEBUG_REQ(D_ERROR, req, "faked source MDT");
svc_rc = SECSVC_DROP;
}
break;
case LUSTRE_SP_OST:
if (!req->rq_auth_usr_ost) {
DEBUG_REQ(D_ERROR, req, "faked source OST");
svc_rc = SECSVC_DROP;
}
break;
case LUSTRE_SP_MGS:
case LUSTRE_SP_MGC:
if (!req->rq_auth_usr_root && !req->rq_auth_usr_mdt &&
!req->rq_auth_usr_ost) {
DEBUG_REQ(D_ERROR, req, "faked source MGC/MGS");
svc_rc = SECSVC_DROP;
}
break;
case LUSTRE_SP_ANY:
default:
DEBUG_REQ(D_ERROR, req, "invalid source %u", req->rq_sp_from);
svc_rc = SECSVC_DROP;
}
return svc_rc;
}
/**
* Used by ptlrpc server, to perform transformation upon request message of
* incoming \a req. This must be the first thing to do with a incoming
* request in ptlrpc layer.
*
* \retval SECSVC_OK success, and req->rq_reqmsg point to request message in
* clear text, size is req->rq_reqlen; also req->rq_svc_ctx is set.
* \retval SECSVC_COMPLETE success, the request has been fully processed, and
* reply message has been prepared.
* \retval SECSVC_DROP failed, this request should be dropped.
*/
int sptlrpc_svc_unwrap_request(struct ptlrpc_request *req)
{
struct ptlrpc_sec_policy *policy;
struct lustre_msg *msg = req->rq_reqbuf;
int rc;
LASSERT(msg);
LASSERT(req->rq_reqmsg == NULL);
LASSERT(req->rq_repmsg == NULL);
LASSERT(req->rq_svc_ctx == NULL);
req->rq_req_swab_mask = 0;
rc = __lustre_unpack_msg(msg, req->rq_reqdata_len);
switch (rc) {
case 1:
lustre_set_req_swabbed(req, MSG_PTLRPC_HEADER_OFF);
case 0:
break;
default:
CERROR("error unpacking request from %s x%llu\n",
libcfs_id2str(req->rq_peer), req->rq_xid);
return SECSVC_DROP;
}
req->rq_flvr.sf_rpc = WIRE_FLVR(msg->lm_secflvr);
req->rq_sp_from = LUSTRE_SP_ANY;
req->rq_auth_uid = -1;
req->rq_auth_mapped_uid = -1;
policy = sptlrpc_wireflavor2policy(req->rq_flvr.sf_rpc);
if (!policy) {
CERROR("unsupported rpc flavor %x\n", req->rq_flvr.sf_rpc);
return SECSVC_DROP;
}
LASSERT(policy->sp_sops->accept);
rc = policy->sp_sops->accept(req);
sptlrpc_policy_put(policy);
LASSERT(req->rq_reqmsg || rc != SECSVC_OK);
LASSERT(req->rq_svc_ctx || rc == SECSVC_DROP);
/*
* if it's not null flavor (which means embedded packing msg),
* reset the swab mask for the coming inner msg unpacking.
*/
if (SPTLRPC_FLVR_POLICY(req->rq_flvr.sf_rpc) != SPTLRPC_POLICY_NULL)
req->rq_req_swab_mask = 0;
/* sanity check for the request source */
rc = sptlrpc_svc_check_from(req, rc);
return rc;
}
/**
* Used by ptlrpc server, to allocate reply buffer for \a req. If succeed,
* req->rq_reply_state is set, and req->rq_reply_state->rs_msg point to
* a buffer of \a msglen size.
*/
int sptlrpc_svc_alloc_rs(struct ptlrpc_request *req, int msglen)
{
struct ptlrpc_sec_policy *policy;
struct ptlrpc_reply_state *rs;
int rc;
LASSERT(req->rq_svc_ctx);
LASSERT(req->rq_svc_ctx->sc_policy);
policy = req->rq_svc_ctx->sc_policy;
LASSERT(policy->sp_sops->alloc_rs);
rc = policy->sp_sops->alloc_rs(req, msglen);
if (unlikely(rc == -ENOMEM)) {
struct ptlrpc_service_part *svcpt = req->rq_rqbd->rqbd_svcpt;
if (svcpt->scp_service->srv_max_reply_size <
msglen + sizeof(struct ptlrpc_reply_state)) {
/* Just return failure if the size is too big */
CERROR("size of message is too big (%zd), %d allowed",
msglen + sizeof(struct ptlrpc_reply_state),
svcpt->scp_service->srv_max_reply_size);
return -ENOMEM;
}
/* failed alloc, try emergency pool */
rs = lustre_get_emerg_rs(svcpt);
if (rs == NULL)
return -ENOMEM;
req->rq_reply_state = rs;
rc = policy->sp_sops->alloc_rs(req, msglen);
if (rc) {
lustre_put_emerg_rs(rs);
req->rq_reply_state = NULL;
}
}
LASSERT(rc != 0 ||
(req->rq_reply_state && req->rq_reply_state->rs_msg));
return rc;
}
/**
* Used by ptlrpc server, to perform transformation upon reply message.
*
* \post req->rq_reply_off is set to appropriate server-controlled reply offset.
* \post req->rq_repmsg and req->rq_reply_state->rs_msg becomes inaccessible.
*/
int sptlrpc_svc_wrap_reply(struct ptlrpc_request *req)
{
struct ptlrpc_sec_policy *policy;
int rc;
LASSERT(req->rq_svc_ctx);
LASSERT(req->rq_svc_ctx->sc_policy);
policy = req->rq_svc_ctx->sc_policy;
LASSERT(policy->sp_sops->authorize);
rc = policy->sp_sops->authorize(req);
LASSERT(rc || req->rq_reply_state->rs_repdata_len);
return rc;
}
/**
* Used by ptlrpc server, to free reply_state.
*/
void sptlrpc_svc_free_rs(struct ptlrpc_reply_state *rs)
{
struct ptlrpc_sec_policy *policy;
unsigned int prealloc;
LASSERT(rs->rs_svc_ctx);
LASSERT(rs->rs_svc_ctx->sc_policy);
policy = rs->rs_svc_ctx->sc_policy;
LASSERT(policy->sp_sops->free_rs);
prealloc = rs->rs_prealloc;
policy->sp_sops->free_rs(rs);
if (prealloc)
lustre_put_emerg_rs(rs);
}
void sptlrpc_svc_ctx_addref(struct ptlrpc_request *req)
{
struct ptlrpc_svc_ctx *ctx = req->rq_svc_ctx;
if (ctx != NULL)
atomic_inc(&ctx->sc_refcount);
}
void sptlrpc_svc_ctx_decref(struct ptlrpc_request *req)
{
struct ptlrpc_svc_ctx *ctx = req->rq_svc_ctx;
if (ctx == NULL)
return;
LASSERT_ATOMIC_POS(&ctx->sc_refcount);
if (atomic_dec_and_test(&ctx->sc_refcount)) {
if (ctx->sc_policy->sp_sops->free_ctx)
ctx->sc_policy->sp_sops->free_ctx(ctx);
}
req->rq_svc_ctx = NULL;
}
void sptlrpc_svc_ctx_invalidate(struct ptlrpc_request *req)
{
struct ptlrpc_svc_ctx *ctx = req->rq_svc_ctx;
if (ctx == NULL)
return;
LASSERT_ATOMIC_POS(&ctx->sc_refcount);
if (ctx->sc_policy->sp_sops->invalidate_ctx)
ctx->sc_policy->sp_sops->invalidate_ctx(ctx);
}
EXPORT_SYMBOL(sptlrpc_svc_ctx_invalidate);
/****************************************
* bulk security *
****************************************/
/**
* Perform transformation upon bulk data pointed by \a desc. This is called
* before transforming the request message.
*/
int sptlrpc_cli_wrap_bulk(struct ptlrpc_request *req,
struct ptlrpc_bulk_desc *desc)
{
struct ptlrpc_cli_ctx *ctx;
LASSERT(req->rq_bulk_read || req->rq_bulk_write);
if (!req->rq_pack_bulk)
return 0;
ctx = req->rq_cli_ctx;
if (ctx->cc_ops->wrap_bulk)
return ctx->cc_ops->wrap_bulk(ctx, req, desc);
return 0;
}
EXPORT_SYMBOL(sptlrpc_cli_wrap_bulk);
/**
* This is called after unwrap the reply message.
* return nob of actual plain text size received, or error code.
*/
int sptlrpc_cli_unwrap_bulk_read(struct ptlrpc_request *req,
struct ptlrpc_bulk_desc *desc,
int nob)
{
struct ptlrpc_cli_ctx *ctx;
int rc;
LASSERT(req->rq_bulk_read && !req->rq_bulk_write);
if (!req->rq_pack_bulk)
return desc->bd_nob_transferred;
ctx = req->rq_cli_ctx;
if (ctx->cc_ops->unwrap_bulk) {
rc = ctx->cc_ops->unwrap_bulk(ctx, req, desc);
if (rc < 0)
return rc;
}
return desc->bd_nob_transferred;
}
EXPORT_SYMBOL(sptlrpc_cli_unwrap_bulk_read);
/**
* This is called after unwrap the reply message.
* return 0 for success or error code.
*/
int sptlrpc_cli_unwrap_bulk_write(struct ptlrpc_request *req,
struct ptlrpc_bulk_desc *desc)
{
struct ptlrpc_cli_ctx *ctx;
int rc;
LASSERT(!req->rq_bulk_read && req->rq_bulk_write);
if (!req->rq_pack_bulk)
return 0;
ctx = req->rq_cli_ctx;
if (ctx->cc_ops->unwrap_bulk) {
rc = ctx->cc_ops->unwrap_bulk(ctx, req, desc);
if (rc < 0)
return rc;
}
/*
* if everything is going right, nob should equals to nob_transferred.
* in case of privacy mode, nob_transferred needs to be adjusted.
*/
if (desc->bd_nob != desc->bd_nob_transferred) {
CERROR("nob %d doesn't match transferred nob %d",
desc->bd_nob, desc->bd_nob_transferred);
return -EPROTO;
}
return 0;
}
EXPORT_SYMBOL(sptlrpc_cli_unwrap_bulk_write);
/****************************************
* user descriptor helpers *
****************************************/
int sptlrpc_current_user_desc_size(void)
{
int ngroups;
ngroups = current_ngroups;
if (ngroups > LUSTRE_MAX_GROUPS)
ngroups = LUSTRE_MAX_GROUPS;
return sptlrpc_user_desc_size(ngroups);
}
EXPORT_SYMBOL(sptlrpc_current_user_desc_size);
int sptlrpc_pack_user_desc(struct lustre_msg *msg, int offset)
{
struct ptlrpc_user_desc *pud;
pud = lustre_msg_buf(msg, offset, 0);
pud->pud_uid = from_kuid(&init_user_ns, current_uid());
pud->pud_gid = from_kgid(&init_user_ns, current_gid());
pud->pud_fsuid = from_kuid(&init_user_ns, current_fsuid());
pud->pud_fsgid = from_kgid(&init_user_ns, current_fsgid());
pud->pud_cap = cfs_curproc_cap_pack();
pud->pud_ngroups = (msg->lm_buflens[offset] - sizeof(*pud)) / 4;
task_lock(current);
if (pud->pud_ngroups > current_ngroups)
pud->pud_ngroups = current_ngroups;
memcpy(pud->pud_groups, current_cred()->group_info->blocks[0],
pud->pud_ngroups * sizeof(__u32));
task_unlock(current);
return 0;
}
EXPORT_SYMBOL(sptlrpc_pack_user_desc);
int sptlrpc_unpack_user_desc(struct lustre_msg *msg, int offset, int swabbed)
{
struct ptlrpc_user_desc *pud;
int i;
pud = lustre_msg_buf(msg, offset, sizeof(*pud));
if (!pud)
return -EINVAL;
if (swabbed) {
__swab32s(&pud->pud_uid);
__swab32s(&pud->pud_gid);
__swab32s(&pud->pud_fsuid);
__swab32s(&pud->pud_fsgid);
__swab32s(&pud->pud_cap);
__swab32s(&pud->pud_ngroups);
}
if (pud->pud_ngroups > LUSTRE_MAX_GROUPS) {
CERROR("%u groups is too large\n", pud->pud_ngroups);
return -EINVAL;
}
if (sizeof(*pud) + pud->pud_ngroups * sizeof(__u32) >
msg->lm_buflens[offset]) {
CERROR("%u groups are claimed but bufsize only %u\n",
pud->pud_ngroups, msg->lm_buflens[offset]);
return -EINVAL;
}
if (swabbed) {
for (i = 0; i < pud->pud_ngroups; i++)
__swab32s(&pud->pud_groups[i]);
}
return 0;
}
EXPORT_SYMBOL(sptlrpc_unpack_user_desc);
/****************************************
* misc helpers *
****************************************/
const char *sec2target_str(struct ptlrpc_sec *sec)
{
if (!sec || !sec->ps_import || !sec->ps_import->imp_obd)
return "*";
if (sec_is_reverse(sec))
return "c";
return obd_uuid2str(&sec->ps_import->imp_obd->u.cli.cl_target_uuid);
}
EXPORT_SYMBOL(sec2target_str);
/*
* return true if the bulk data is protected
*/
int sptlrpc_flavor_has_bulk(struct sptlrpc_flavor *flvr)
{
switch (SPTLRPC_FLVR_BULK_SVC(flvr->sf_rpc)) {
case SPTLRPC_BULK_SVC_INTG:
case SPTLRPC_BULK_SVC_PRIV:
return 1;
default:
return 0;
}
}
EXPORT_SYMBOL(sptlrpc_flavor_has_bulk);
/****************************************
* crypto API helper/alloc blkciper *
****************************************/
/****************************************
* initialize/finalize *
****************************************/
int sptlrpc_init(void)
{
int rc;
rwlock_init(&policy_lock);
rc = sptlrpc_gc_init();
if (rc)
goto out;
rc = sptlrpc_conf_init();
if (rc)
goto out_gc;
rc = sptlrpc_enc_pool_init();
if (rc)
goto out_conf;
rc = sptlrpc_null_init();
if (rc)
goto out_pool;
rc = sptlrpc_plain_init();
if (rc)
goto out_null;
rc = sptlrpc_lproc_init();
if (rc)
goto out_plain;
return 0;
out_plain:
sptlrpc_plain_fini();
out_null:
sptlrpc_null_fini();
out_pool:
sptlrpc_enc_pool_fini();
out_conf:
sptlrpc_conf_fini();
out_gc:
sptlrpc_gc_fini();
out:
return rc;
}
void sptlrpc_fini(void)
{
sptlrpc_lproc_fini();
sptlrpc_plain_fini();
sptlrpc_null_fini();
sptlrpc_enc_pool_fini();
sptlrpc_conf_fini();
sptlrpc_gc_fini();
}