linux/net/sunrpc/xprtrdma/verbs.c

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/*
* Copyright (c) 2003-2007 Network Appliance, Inc. All rights reserved.
*
* This software is available to you under a choice of one of two
* licenses. You may choose to be licensed under the terms of the GNU
* General Public License (GPL) Version 2, available from the file
* COPYING in the main directory of this source tree, or the BSD-type
* license below:
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
*
* Neither the name of the Network Appliance, Inc. nor the names of
* its contributors may be used to endorse or promote products
* derived from this software without specific prior written
* permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* verbs.c
*
* Encapsulates the major functions managing:
* o adapters
* o endpoints
* o connections
* o buffer memory
*/
#include <linux/interrupt.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 08:04:11 +00:00
#include <linux/slab.h>
#include <linux/prefetch.h>
#include <linux/sunrpc/addr.h>
xprtrdma: Reduce the number of hardway buffer allocations While marshaling an RPC/RDMA request, the inline_{rsize,wsize} settings determine whether an inline request is used, or whether read or write chunks lists are built. The current default value of these settings is 1024. Any RPC request smaller than 1024 bytes is sent to the NFS server completely inline. rpcrdma_buffer_create() allocates and pre-registers a set of RPC buffers for each transport instance, also based on the inline rsize and wsize settings. RPC/RDMA requests and replies are built in these buffers. However, if an RPC/RDMA request is expected to be larger than 1024, a buffer has to be allocated and registered for that RPC, and deregistered and released when the RPC is complete. This is known has a "hardway allocation." Since the introduction of NFSv4, the size of RPC requests has become larger, and hardway allocations are thus more frequent. Hardway allocations are significant overhead, and they waste the existing RPC buffers pre-allocated by rpcrdma_buffer_create(). We'd like fewer hardway allocations. Increasing the size of the pre-registered buffers is the most direct way to do this. However, a blanket increase of the inline thresholds has interoperability consequences. On my 64-bit system, rpcrdma_buffer_create() requests roughly 7000 bytes for each RPC request buffer, using kmalloc(). Due to internal fragmentation, this wastes nearly 1200 bytes because kmalloc() already returns an 8192-byte piece of memory for a 7000-byte allocation request, though the extra space remains unused. So let's round up the size of the pre-allocated buffers, and make use of the unused space in the kmalloc'd memory. This change reduces the amount of hardway allocated memory for an NFSv4 general connectathon run from 1322092 to 9472 bytes (99%). Signed-off-by: Chuck Lever <chuck.lever@oracle.com> Tested-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Anna Schumaker <Anna.Schumaker@Netapp.com>
2014-05-28 14:33:59 +00:00
#include <asm/bitops.h>
#include <linux/module.h> /* try_module_get()/module_put() */
#include "xprt_rdma.h"
/*
* Globals/Macros
*/
#if IS_ENABLED(CONFIG_SUNRPC_DEBUG)
# define RPCDBG_FACILITY RPCDBG_TRANS
#endif
/*
* internal functions
*/
static struct workqueue_struct *rpcrdma_receive_wq;
int
rpcrdma_alloc_wq(void)
{
struct workqueue_struct *recv_wq;
recv_wq = alloc_workqueue("xprtrdma_receive",
WQ_MEM_RECLAIM | WQ_UNBOUND | WQ_HIGHPRI,
0);
if (!recv_wq)
return -ENOMEM;
rpcrdma_receive_wq = recv_wq;
return 0;
}
void
rpcrdma_destroy_wq(void)
{
struct workqueue_struct *wq;
if (rpcrdma_receive_wq) {
wq = rpcrdma_receive_wq;
rpcrdma_receive_wq = NULL;
destroy_workqueue(wq);
}
}
static void
rpcrdma_qp_async_error_upcall(struct ib_event *event, void *context)
{
struct rpcrdma_ep *ep = context;
pr_err("RPC: %s: %s on device %s ep %p\n",
__func__, ib_event_msg(event->event),
event->device->name, context);
if (ep->rep_connected == 1) {
ep->rep_connected = -EIO;
rpcrdma_conn_func(ep);
wake_up_all(&ep->rep_connect_wait);
}
}
static void
rpcrdma_cq_async_error_upcall(struct ib_event *event, void *context)
{
struct rpcrdma_ep *ep = context;
pr_err("RPC: %s: %s on device %s ep %p\n",
__func__, ib_event_msg(event->event),
event->device->name, context);
if (ep->rep_connected == 1) {
ep->rep_connected = -EIO;
rpcrdma_conn_func(ep);
wake_up_all(&ep->rep_connect_wait);
}
}
static void
rpcrdma_sendcq_process_wc(struct ib_wc *wc)
{
/* WARNING: Only wr_id and status are reliable at this point */
if (wc->wr_id == RPCRDMA_IGNORE_COMPLETION) {
if (wc->status != IB_WC_SUCCESS &&
wc->status != IB_WC_WR_FLUSH_ERR)
pr_err("RPC: %s: SEND: %s\n",
__func__, ib_wc_status_msg(wc->status));
} else {
struct rpcrdma_mw *r;
r = (struct rpcrdma_mw *)(unsigned long)wc->wr_id;
r->mw_sendcompletion(wc);
}
}
/* The common case is a single send completion is waiting. By
* passing two WC entries to ib_poll_cq, a return code of 1
* means there is exactly one WC waiting and no more. We don't
* have to invoke ib_poll_cq again to know that the CQ has been
* properly drained.
*/
static void
rpcrdma_sendcq_poll(struct ib_cq *cq)
{
struct ib_wc *pos, wcs[2];
int count, rc;
do {
pos = wcs;
rc = ib_poll_cq(cq, ARRAY_SIZE(wcs), pos);
if (rc < 0)
break;
count = rc;
while (count-- > 0)
rpcrdma_sendcq_process_wc(pos++);
} while (rc == ARRAY_SIZE(wcs));
return;
}
/* Handle provider send completion upcalls.
*/
static void
rpcrdma_sendcq_upcall(struct ib_cq *cq, void *cq_context)
{
do {
rpcrdma_sendcq_poll(cq);
} while (ib_req_notify_cq(cq, IB_CQ_NEXT_COMP |
IB_CQ_REPORT_MISSED_EVENTS) > 0);
}
static void
rpcrdma_receive_worker(struct work_struct *work)
{
struct rpcrdma_rep *rep =
container_of(work, struct rpcrdma_rep, rr_work);
rpcrdma_reply_handler(rep);
}
static void
rpcrdma_recvcq_process_wc(struct ib_wc *wc)
{
struct rpcrdma_rep *rep =
(struct rpcrdma_rep *)(unsigned long)wc->wr_id;
/* WARNING: Only wr_id and status are reliable at this point */
if (wc->status != IB_WC_SUCCESS)
goto out_fail;
/* status == SUCCESS means all fields in wc are trustworthy */
if (wc->opcode != IB_WC_RECV)
return;
dprintk("RPC: %s: rep %p opcode 'recv', length %u: success\n",
__func__, rep, wc->byte_len);
rep->rr_len = wc->byte_len;
ib_dma_sync_single_for_cpu(rep->rr_device,
rdmab_addr(rep->rr_rdmabuf),
rep->rr_len, DMA_FROM_DEVICE);
prefetch(rdmab_to_msg(rep->rr_rdmabuf));
out_schedule:
queue_work(rpcrdma_receive_wq, &rep->rr_work);
return;
out_fail:
if (wc->status != IB_WC_WR_FLUSH_ERR)
pr_err("RPC: %s: rep %p: %s\n",
__func__, rep, ib_wc_status_msg(wc->status));
rep->rr_len = RPCRDMA_BAD_LEN;
goto out_schedule;
}
/* The wc array is on stack: automatic memory is always CPU-local.
*
* struct ib_wc is 64 bytes, making the poll array potentially
* large. But this is at the bottom of the call chain. Further
* substantial work is done in another thread.
*/
static void
rpcrdma_recvcq_poll(struct ib_cq *cq)
{
struct ib_wc *pos, wcs[4];
int count, rc;
do {
pos = wcs;
rc = ib_poll_cq(cq, ARRAY_SIZE(wcs), pos);
if (rc < 0)
break;
count = rc;
while (count-- > 0)
rpcrdma_recvcq_process_wc(pos++);
} while (rc == ARRAY_SIZE(wcs));
}
/* Handle provider receive completion upcalls.
*/
static void
rpcrdma_recvcq_upcall(struct ib_cq *cq, void *cq_context)
{
do {
rpcrdma_recvcq_poll(cq);
} while (ib_req_notify_cq(cq, IB_CQ_NEXT_COMP |
IB_CQ_REPORT_MISSED_EVENTS) > 0);
}
static void
rpcrdma_flush_cqs(struct rpcrdma_ep *ep)
{
struct ib_wc wc;
while (ib_poll_cq(ep->rep_attr.recv_cq, 1, &wc) > 0)
rpcrdma_recvcq_process_wc(&wc);
while (ib_poll_cq(ep->rep_attr.send_cq, 1, &wc) > 0)
rpcrdma_sendcq_process_wc(&wc);
}
static int
rpcrdma_conn_upcall(struct rdma_cm_id *id, struct rdma_cm_event *event)
{
struct rpcrdma_xprt *xprt = id->context;
struct rpcrdma_ia *ia = &xprt->rx_ia;
struct rpcrdma_ep *ep = &xprt->rx_ep;
#if IS_ENABLED(CONFIG_SUNRPC_DEBUG)
struct sockaddr *sap = (struct sockaddr *)&ep->rep_remote_addr;
#endif
struct ib_qp_attr *attr = &ia->ri_qp_attr;
struct ib_qp_init_attr *iattr = &ia->ri_qp_init_attr;
int connstate = 0;
switch (event->event) {
case RDMA_CM_EVENT_ADDR_RESOLVED:
case RDMA_CM_EVENT_ROUTE_RESOLVED:
ia->ri_async_rc = 0;
complete(&ia->ri_done);
break;
case RDMA_CM_EVENT_ADDR_ERROR:
ia->ri_async_rc = -EHOSTUNREACH;
dprintk("RPC: %s: CM address resolution error, ep 0x%p\n",
__func__, ep);
complete(&ia->ri_done);
break;
case RDMA_CM_EVENT_ROUTE_ERROR:
ia->ri_async_rc = -ENETUNREACH;
dprintk("RPC: %s: CM route resolution error, ep 0x%p\n",
__func__, ep);
complete(&ia->ri_done);
break;
case RDMA_CM_EVENT_ESTABLISHED:
connstate = 1;
ib_query_qp(ia->ri_id->qp, attr,
IB_QP_MAX_QP_RD_ATOMIC | IB_QP_MAX_DEST_RD_ATOMIC,
iattr);
dprintk("RPC: %s: %d responder resources"
" (%d initiator)\n",
__func__, attr->max_dest_rd_atomic,
attr->max_rd_atomic);
goto connected;
case RDMA_CM_EVENT_CONNECT_ERROR:
connstate = -ENOTCONN;
goto connected;
case RDMA_CM_EVENT_UNREACHABLE:
connstate = -ENETDOWN;
goto connected;
case RDMA_CM_EVENT_REJECTED:
connstate = -ECONNREFUSED;
goto connected;
case RDMA_CM_EVENT_DISCONNECTED:
connstate = -ECONNABORTED;
goto connected;
case RDMA_CM_EVENT_DEVICE_REMOVAL:
connstate = -ENODEV;
connected:
dprintk("RPC: %s: %sconnected\n",
__func__, connstate > 0 ? "" : "dis");
ep->rep_connected = connstate;
rpcrdma_conn_func(ep);
wake_up_all(&ep->rep_connect_wait);
/*FALLTHROUGH*/
default:
dprintk("RPC: %s: %pIS:%u (ep 0x%p): %s\n",
__func__, sap, rpc_get_port(sap), ep,
rdma_event_msg(event->event));
break;
}
#if IS_ENABLED(CONFIG_SUNRPC_DEBUG)
if (connstate == 1) {
int ird = attr->max_dest_rd_atomic;
int tird = ep->rep_remote_cma.responder_resources;
pr_info("rpcrdma: connection to %pIS:%u on %s, memreg '%s', %d credits, %d responders%s\n",
sap, rpc_get_port(sap),
ia->ri_device->name,
ia->ri_ops->ro_displayname,
xprt->rx_buf.rb_max_requests,
ird, ird < 4 && ird < tird / 2 ? " (low!)" : "");
} else if (connstate < 0) {
pr_info("rpcrdma: connection to %pIS:%u closed (%d)\n",
sap, rpc_get_port(sap), connstate);
}
#endif
return 0;
}
static void rpcrdma_destroy_id(struct rdma_cm_id *id)
{
if (id) {
module_put(id->device->owner);
rdma_destroy_id(id);
}
}
static struct rdma_cm_id *
rpcrdma_create_id(struct rpcrdma_xprt *xprt,
struct rpcrdma_ia *ia, struct sockaddr *addr)
{
struct rdma_cm_id *id;
int rc;
init_completion(&ia->ri_done);
id = rdma_create_id(&init_net, rpcrdma_conn_upcall, xprt, RDMA_PS_TCP,
IB_QPT_RC);
if (IS_ERR(id)) {
rc = PTR_ERR(id);
dprintk("RPC: %s: rdma_create_id() failed %i\n",
__func__, rc);
return id;
}
ia->ri_async_rc = -ETIMEDOUT;
rc = rdma_resolve_addr(id, NULL, addr, RDMA_RESOLVE_TIMEOUT);
if (rc) {
dprintk("RPC: %s: rdma_resolve_addr() failed %i\n",
__func__, rc);
goto out;
}
wait_for_completion_interruptible_timeout(&ia->ri_done,
msecs_to_jiffies(RDMA_RESOLVE_TIMEOUT) + 1);
/* FIXME:
* Until xprtrdma supports DEVICE_REMOVAL, the provider must
* be pinned while there are active NFS/RDMA mounts to prevent
* hangs and crashes at umount time.
*/
if (!ia->ri_async_rc && !try_module_get(id->device->owner)) {
dprintk("RPC: %s: Failed to get device module\n",
__func__);
ia->ri_async_rc = -ENODEV;
}
rc = ia->ri_async_rc;
if (rc)
goto out;
ia->ri_async_rc = -ETIMEDOUT;
rc = rdma_resolve_route(id, RDMA_RESOLVE_TIMEOUT);
if (rc) {
dprintk("RPC: %s: rdma_resolve_route() failed %i\n",
__func__, rc);
goto put;
}
wait_for_completion_interruptible_timeout(&ia->ri_done,
msecs_to_jiffies(RDMA_RESOLVE_TIMEOUT) + 1);
rc = ia->ri_async_rc;
if (rc)
goto put;
return id;
put:
module_put(id->device->owner);
out:
rdma_destroy_id(id);
return ERR_PTR(rc);
}
/*
* Drain any cq, prior to teardown.
*/
static void
rpcrdma_clean_cq(struct ib_cq *cq)
{
struct ib_wc wc;
int count = 0;
while (1 == ib_poll_cq(cq, 1, &wc))
++count;
if (count)
dprintk("RPC: %s: flushed %d events (last 0x%x)\n",
__func__, count, wc.opcode);
}
/*
* Exported functions.
*/
/*
* Open and initialize an Interface Adapter.
* o initializes fields of struct rpcrdma_ia, including
* interface and provider attributes and protection zone.
*/
int
rpcrdma_ia_open(struct rpcrdma_xprt *xprt, struct sockaddr *addr, int memreg)
{
struct rpcrdma_ia *ia = &xprt->rx_ia;
struct ib_device_attr *devattr = &ia->ri_devattr;
int rc;
ia->ri_dma_mr = NULL;
ia->ri_id = rpcrdma_create_id(xprt, ia, addr);
if (IS_ERR(ia->ri_id)) {
rc = PTR_ERR(ia->ri_id);
goto out1;
}
ia->ri_device = ia->ri_id->device;
ia->ri_pd = ib_alloc_pd(ia->ri_device);
if (IS_ERR(ia->ri_pd)) {
rc = PTR_ERR(ia->ri_pd);
dprintk("RPC: %s: ib_alloc_pd() failed %i\n",
__func__, rc);
goto out2;
}
rc = ib_query_device(ia->ri_device, devattr);
if (rc) {
dprintk("RPC: %s: ib_query_device failed %d\n",
__func__, rc);
goto out3;
}
if (memreg == RPCRDMA_FRMR) {
if (!(devattr->device_cap_flags & IB_DEVICE_MEM_MGT_EXTENSIONS) ||
(devattr->max_fast_reg_page_list_len == 0)) {
dprintk("RPC: %s: FRMR registration "
"not supported by HCA\n", __func__);
memreg = RPCRDMA_MTHCAFMR;
}
}
if (memreg == RPCRDMA_MTHCAFMR) {
if (!ia->ri_device->alloc_fmr) {
dprintk("RPC: %s: MTHCAFMR registration "
"not supported by HCA\n", __func__);
rc = -EINVAL;
goto out3;
}
}
switch (memreg) {
case RPCRDMA_FRMR:
ia->ri_ops = &rpcrdma_frwr_memreg_ops;
break;
case RPCRDMA_ALLPHYSICAL:
ia->ri_ops = &rpcrdma_physical_memreg_ops;
break;
case RPCRDMA_MTHCAFMR:
ia->ri_ops = &rpcrdma_fmr_memreg_ops;
break;
default:
printk(KERN_ERR "RPC: Unsupported memory "
"registration mode: %d\n", memreg);
rc = -ENOMEM;
goto out3;
}
dprintk("RPC: %s: memory registration strategy is '%s'\n",
__func__, ia->ri_ops->ro_displayname);
rwlock_init(&ia->ri_qplock);
return 0;
out3:
ib_dealloc_pd(ia->ri_pd);
ia->ri_pd = NULL;
out2:
rpcrdma_destroy_id(ia->ri_id);
ia->ri_id = NULL;
out1:
return rc;
}
/*
* Clean up/close an IA.
* o if event handles and PD have been initialized, free them.
* o close the IA
*/
void
rpcrdma_ia_close(struct rpcrdma_ia *ia)
{
dprintk("RPC: %s: entering\n", __func__);
if (ia->ri_id != NULL && !IS_ERR(ia->ri_id)) {
if (ia->ri_id->qp)
rdma_destroy_qp(ia->ri_id);
rpcrdma_destroy_id(ia->ri_id);
ia->ri_id = NULL;
}
/* If the pd is still busy, xprtrdma missed freeing a resource */
if (ia->ri_pd && !IS_ERR(ia->ri_pd))
ib_dealloc_pd(ia->ri_pd);
}
/*
* Create unconnected endpoint.
*/
int
rpcrdma_ep_create(struct rpcrdma_ep *ep, struct rpcrdma_ia *ia,
struct rpcrdma_create_data_internal *cdata)
{
struct ib_device_attr *devattr = &ia->ri_devattr;
struct ib_cq *sendcq, *recvcq;
struct ib_cq_init_attr cq_attr = {};
unsigned int max_qp_wr;
int rc, err;
if (devattr->max_sge < RPCRDMA_MAX_IOVS) {
dprintk("RPC: %s: insufficient sge's available\n",
__func__);
return -ENOMEM;
}
if (devattr->max_qp_wr <= RPCRDMA_BACKWARD_WRS) {
dprintk("RPC: %s: insufficient wqe's available\n",
__func__);
return -ENOMEM;
}
max_qp_wr = devattr->max_qp_wr - RPCRDMA_BACKWARD_WRS;
/* check provider's send/recv wr limits */
if (cdata->max_requests > max_qp_wr)
cdata->max_requests = max_qp_wr;
ep->rep_attr.event_handler = rpcrdma_qp_async_error_upcall;
ep->rep_attr.qp_context = ep;
ep->rep_attr.srq = NULL;
ep->rep_attr.cap.max_send_wr = cdata->max_requests;
ep->rep_attr.cap.max_send_wr += RPCRDMA_BACKWARD_WRS;
rc = ia->ri_ops->ro_open(ia, ep, cdata);
if (rc)
return rc;
ep->rep_attr.cap.max_recv_wr = cdata->max_requests;
ep->rep_attr.cap.max_recv_wr += RPCRDMA_BACKWARD_WRS;
ep->rep_attr.cap.max_send_sge = RPCRDMA_MAX_IOVS;
ep->rep_attr.cap.max_recv_sge = 1;
ep->rep_attr.cap.max_inline_data = 0;
ep->rep_attr.sq_sig_type = IB_SIGNAL_REQ_WR;
ep->rep_attr.qp_type = IB_QPT_RC;
ep->rep_attr.port_num = ~0;
dprintk("RPC: %s: requested max: dtos: send %d recv %d; "
"iovs: send %d recv %d\n",
__func__,
ep->rep_attr.cap.max_send_wr,
ep->rep_attr.cap.max_recv_wr,
ep->rep_attr.cap.max_send_sge,
ep->rep_attr.cap.max_recv_sge);
/* set trigger for requesting send completion */
ep->rep_cqinit = ep->rep_attr.cap.max_send_wr/2 - 1;
if (ep->rep_cqinit > RPCRDMA_MAX_UNSIGNALED_SENDS)
ep->rep_cqinit = RPCRDMA_MAX_UNSIGNALED_SENDS;
else if (ep->rep_cqinit <= 2)
ep->rep_cqinit = 0;
INIT_CQCOUNT(ep);
init_waitqueue_head(&ep->rep_connect_wait);
INIT_DELAYED_WORK(&ep->rep_connect_worker, rpcrdma_connect_worker);
cq_attr.cqe = ep->rep_attr.cap.max_send_wr + 1;
sendcq = ib_create_cq(ia->ri_device, rpcrdma_sendcq_upcall,
rpcrdma_cq_async_error_upcall, NULL, &cq_attr);
if (IS_ERR(sendcq)) {
rc = PTR_ERR(sendcq);
dprintk("RPC: %s: failed to create send CQ: %i\n",
__func__, rc);
goto out1;
}
rc = ib_req_notify_cq(sendcq, IB_CQ_NEXT_COMP);
if (rc) {
dprintk("RPC: %s: ib_req_notify_cq failed: %i\n",
__func__, rc);
goto out2;
}
cq_attr.cqe = ep->rep_attr.cap.max_recv_wr + 1;
recvcq = ib_create_cq(ia->ri_device, rpcrdma_recvcq_upcall,
rpcrdma_cq_async_error_upcall, NULL, &cq_attr);
if (IS_ERR(recvcq)) {
rc = PTR_ERR(recvcq);
dprintk("RPC: %s: failed to create recv CQ: %i\n",
__func__, rc);
goto out2;
}
rc = ib_req_notify_cq(recvcq, IB_CQ_NEXT_COMP);
if (rc) {
dprintk("RPC: %s: ib_req_notify_cq failed: %i\n",
__func__, rc);
ib_destroy_cq(recvcq);
goto out2;
}
ep->rep_attr.send_cq = sendcq;
ep->rep_attr.recv_cq = recvcq;
/* Initialize cma parameters */
/* RPC/RDMA does not use private data */
ep->rep_remote_cma.private_data = NULL;
ep->rep_remote_cma.private_data_len = 0;
/* Client offers RDMA Read but does not initiate */
ep->rep_remote_cma.initiator_depth = 0;
if (devattr->max_qp_rd_atom > 32) /* arbitrary but <= 255 */
ep->rep_remote_cma.responder_resources = 32;
else
ep->rep_remote_cma.responder_resources =
devattr->max_qp_rd_atom;
ep->rep_remote_cma.retry_count = 7;
ep->rep_remote_cma.flow_control = 0;
ep->rep_remote_cma.rnr_retry_count = 0;
return 0;
out2:
err = ib_destroy_cq(sendcq);
if (err)
dprintk("RPC: %s: ib_destroy_cq returned %i\n",
__func__, err);
out1:
if (ia->ri_dma_mr)
ib_dereg_mr(ia->ri_dma_mr);
return rc;
}
/*
* rpcrdma_ep_destroy
*
* Disconnect and destroy endpoint. After this, the only
* valid operations on the ep are to free it (if dynamically
* allocated) or re-create it.
*/
void
rpcrdma_ep_destroy(struct rpcrdma_ep *ep, struct rpcrdma_ia *ia)
{
int rc;
dprintk("RPC: %s: entering, connected is %d\n",
__func__, ep->rep_connected);
cancel_delayed_work_sync(&ep->rep_connect_worker);
if (ia->ri_id->qp)
rpcrdma_ep_disconnect(ep, ia);
rpcrdma_clean_cq(ep->rep_attr.recv_cq);
rpcrdma_clean_cq(ep->rep_attr.send_cq);
if (ia->ri_id->qp) {
rdma_destroy_qp(ia->ri_id);
ia->ri_id->qp = NULL;
}
rc = ib_destroy_cq(ep->rep_attr.recv_cq);
if (rc)
dprintk("RPC: %s: ib_destroy_cq returned %i\n",
__func__, rc);
rc = ib_destroy_cq(ep->rep_attr.send_cq);
if (rc)
dprintk("RPC: %s: ib_destroy_cq returned %i\n",
__func__, rc);
if (ia->ri_dma_mr) {
rc = ib_dereg_mr(ia->ri_dma_mr);
dprintk("RPC: %s: ib_dereg_mr returned %i\n",
__func__, rc);
}
}
/*
* Connect unconnected endpoint.
*/
int
rpcrdma_ep_connect(struct rpcrdma_ep *ep, struct rpcrdma_ia *ia)
{
struct rdma_cm_id *id, *old;
int rc = 0;
int retry_count = 0;
if (ep->rep_connected != 0) {
struct rpcrdma_xprt *xprt;
retry:
dprintk("RPC: %s: reconnecting...\n", __func__);
rpcrdma_ep_disconnect(ep, ia);
rpcrdma_flush_cqs(ep);
xprt = container_of(ia, struct rpcrdma_xprt, rx_ia);
id = rpcrdma_create_id(xprt, ia,
(struct sockaddr *)&xprt->rx_data.addr);
if (IS_ERR(id)) {
rc = -EHOSTUNREACH;
goto out;
}
/* TEMP TEMP TEMP - fail if new device:
* Deregister/remarshal *all* requests!
* Close and recreate adapter, pd, etc!
* Re-determine all attributes still sane!
* More stuff I haven't thought of!
* Rrrgh!
*/
if (ia->ri_device != id->device) {
printk("RPC: %s: can't reconnect on "
"different device!\n", __func__);
rpcrdma_destroy_id(id);
rc = -ENETUNREACH;
goto out;
}
/* END TEMP */
rc = rdma_create_qp(id, ia->ri_pd, &ep->rep_attr);
if (rc) {
dprintk("RPC: %s: rdma_create_qp failed %i\n",
__func__, rc);
rpcrdma_destroy_id(id);
rc = -ENETUNREACH;
goto out;
}
write_lock(&ia->ri_qplock);
old = ia->ri_id;
ia->ri_id = id;
write_unlock(&ia->ri_qplock);
rdma_destroy_qp(old);
rpcrdma_destroy_id(old);
} else {
dprintk("RPC: %s: connecting...\n", __func__);
rc = rdma_create_qp(ia->ri_id, ia->ri_pd, &ep->rep_attr);
if (rc) {
dprintk("RPC: %s: rdma_create_qp failed %i\n",
__func__, rc);
/* do not update ep->rep_connected */
return -ENETUNREACH;
}
}
ep->rep_connected = 0;
rc = rdma_connect(ia->ri_id, &ep->rep_remote_cma);
if (rc) {
dprintk("RPC: %s: rdma_connect() failed with %i\n",
__func__, rc);
goto out;
}
wait_event_interruptible(ep->rep_connect_wait, ep->rep_connected != 0);
/*
* Check state. A non-peer reject indicates no listener
* (ECONNREFUSED), which may be a transient state. All
* others indicate a transport condition which has already
* undergone a best-effort.
*/
if (ep->rep_connected == -ECONNREFUSED &&
++retry_count <= RDMA_CONNECT_RETRY_MAX) {
dprintk("RPC: %s: non-peer_reject, retry\n", __func__);
goto retry;
}
if (ep->rep_connected <= 0) {
/* Sometimes, the only way to reliably connect to remote
* CMs is to use same nonzero values for ORD and IRD. */
if (retry_count++ <= RDMA_CONNECT_RETRY_MAX + 1 &&
(ep->rep_remote_cma.responder_resources == 0 ||
ep->rep_remote_cma.initiator_depth !=
ep->rep_remote_cma.responder_resources)) {
if (ep->rep_remote_cma.responder_resources == 0)
ep->rep_remote_cma.responder_resources = 1;
ep->rep_remote_cma.initiator_depth =
ep->rep_remote_cma.responder_resources;
goto retry;
}
rc = ep->rep_connected;
} else {
struct rpcrdma_xprt *r_xprt;
unsigned int extras;
dprintk("RPC: %s: connected\n", __func__);
r_xprt = container_of(ia, struct rpcrdma_xprt, rx_ia);
extras = r_xprt->rx_buf.rb_bc_srv_max_requests;
if (extras) {
rc = rpcrdma_ep_post_extra_recv(r_xprt, extras);
if (rc) {
pr_warn("%s: rpcrdma_ep_post_extra_recv: %i\n",
__func__, rc);
rc = 0;
}
}
}
out:
if (rc)
ep->rep_connected = rc;
return rc;
}
/*
* rpcrdma_ep_disconnect
*
* This is separate from destroy to facilitate the ability
* to reconnect without recreating the endpoint.
*
* This call is not reentrant, and must not be made in parallel
* on the same endpoint.
*/
void
rpcrdma_ep_disconnect(struct rpcrdma_ep *ep, struct rpcrdma_ia *ia)
{
int rc;
rpcrdma_flush_cqs(ep);
rc = rdma_disconnect(ia->ri_id);
if (!rc) {
/* returns without wait if not connected */
wait_event_interruptible(ep->rep_connect_wait,
ep->rep_connected != 1);
dprintk("RPC: %s: after wait, %sconnected\n", __func__,
(ep->rep_connected == 1) ? "still " : "dis");
} else {
dprintk("RPC: %s: rdma_disconnect %i\n", __func__, rc);
ep->rep_connected = rc;
}
}
struct rpcrdma_req *
rpcrdma_create_req(struct rpcrdma_xprt *r_xprt)
{
struct rpcrdma_buffer *buffer = &r_xprt->rx_buf;
struct rpcrdma_req *req;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (req == NULL)
return ERR_PTR(-ENOMEM);
INIT_LIST_HEAD(&req->rl_free);
spin_lock(&buffer->rb_reqslock);
list_add(&req->rl_all, &buffer->rb_allreqs);
spin_unlock(&buffer->rb_reqslock);
req->rl_buffer = &r_xprt->rx_buf;
return req;
}
struct rpcrdma_rep *
rpcrdma_create_rep(struct rpcrdma_xprt *r_xprt)
{
struct rpcrdma_create_data_internal *cdata = &r_xprt->rx_data;
struct rpcrdma_ia *ia = &r_xprt->rx_ia;
struct rpcrdma_rep *rep;
int rc;
rc = -ENOMEM;
rep = kzalloc(sizeof(*rep), GFP_KERNEL);
if (rep == NULL)
goto out;
rep->rr_rdmabuf = rpcrdma_alloc_regbuf(ia, cdata->inline_rsize,
GFP_KERNEL);
if (IS_ERR(rep->rr_rdmabuf)) {
rc = PTR_ERR(rep->rr_rdmabuf);
goto out_free;
}
rep->rr_device = ia->ri_device;
rep->rr_rxprt = r_xprt;
INIT_WORK(&rep->rr_work, rpcrdma_receive_worker);
return rep;
out_free:
kfree(rep);
out:
return ERR_PTR(rc);
}
int
rpcrdma_buffer_create(struct rpcrdma_xprt *r_xprt)
{
struct rpcrdma_buffer *buf = &r_xprt->rx_buf;
struct rpcrdma_ia *ia = &r_xprt->rx_ia;
int i, rc;
buf->rb_max_requests = r_xprt->rx_data.max_requests;
buf->rb_bc_srv_max_requests = 0;
spin_lock_init(&buf->rb_lock);
rc = ia->ri_ops->ro_init(r_xprt);
if (rc)
goto out;
INIT_LIST_HEAD(&buf->rb_send_bufs);
INIT_LIST_HEAD(&buf->rb_allreqs);
spin_lock_init(&buf->rb_reqslock);
for (i = 0; i < buf->rb_max_requests; i++) {
struct rpcrdma_req *req;
req = rpcrdma_create_req(r_xprt);
if (IS_ERR(req)) {
dprintk("RPC: %s: request buffer %d alloc"
" failed\n", __func__, i);
rc = PTR_ERR(req);
goto out;
}
req->rl_backchannel = false;
list_add(&req->rl_free, &buf->rb_send_bufs);
}
INIT_LIST_HEAD(&buf->rb_recv_bufs);
for (i = 0; i < buf->rb_max_requests + 2; i++) {
struct rpcrdma_rep *rep;
rep = rpcrdma_create_rep(r_xprt);
if (IS_ERR(rep)) {
dprintk("RPC: %s: reply buffer %d alloc failed\n",
__func__, i);
rc = PTR_ERR(rep);
goto out;
}
list_add(&rep->rr_list, &buf->rb_recv_bufs);
}
return 0;
out:
rpcrdma_buffer_destroy(buf);
return rc;
}
static struct rpcrdma_req *
rpcrdma_buffer_get_req_locked(struct rpcrdma_buffer *buf)
{
struct rpcrdma_req *req;
req = list_first_entry(&buf->rb_send_bufs,
struct rpcrdma_req, rl_free);
list_del(&req->rl_free);
return req;
}
static struct rpcrdma_rep *
rpcrdma_buffer_get_rep_locked(struct rpcrdma_buffer *buf)
{
struct rpcrdma_rep *rep;
rep = list_first_entry(&buf->rb_recv_bufs,
struct rpcrdma_rep, rr_list);
list_del(&rep->rr_list);
return rep;
}
static void
rpcrdma_destroy_rep(struct rpcrdma_ia *ia, struct rpcrdma_rep *rep)
{
rpcrdma_free_regbuf(ia, rep->rr_rdmabuf);
kfree(rep);
}
void
rpcrdma_destroy_req(struct rpcrdma_ia *ia, struct rpcrdma_req *req)
{
xprtrdma: Allocate RPC send buffer separately from struct rpcrdma_req Because internal memory registration is an expensive and synchronous operation, xprtrdma pre-registers send and receive buffers at mount time, and then re-uses them for each RPC. A "hardway" allocation is a memory allocation and registration that replaces a send buffer during the processing of an RPC. Hardway must be done if the RPC send buffer is too small to accommodate an RPC's call and reply headers. For xprtrdma, each RPC send buffer is currently part of struct rpcrdma_req so that xprt_rdma_free(), which is passed nothing but the address of an RPC send buffer, can find its matching struct rpcrdma_req and rpcrdma_rep quickly via container_of / offsetof. That means that hardway currently has to replace a whole rpcrmda_req when it replaces an RPC send buffer. This is often a fairly hefty chunk of contiguous memory due to the size of the rl_segments array and the fact that both the send and receive buffers are part of struct rpcrdma_req. Some obscure re-use of fields in rpcrdma_req is done so that xprt_rdma_free() can detect replaced rpcrdma_req structs, and restore the original. This commit breaks apart the RPC send buffer and struct rpcrdma_req so that increasing the size of the rl_segments array does not change the alignment of each RPC send buffer. (Increasing rl_segments is needed to bump up the maximum r/wsize for NFS/RDMA). This change opens up some interesting possibilities for improving the design of xprt_rdma_allocate(). xprt_rdma_allocate() is now the one place where RPC send buffers are allocated or re-allocated, and they are now always left in place by xprt_rdma_free(). A large re-allocation that includes both the rl_segments array and the RPC send buffer is no longer needed. Send buffer re-allocation becomes quite rare. Good send buffer alignment is guaranteed no matter what the size of the rl_segments array is. Signed-off-by: Chuck Lever <chuck.lever@oracle.com> Reviewed-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Anna Schumaker <Anna.Schumaker@Netapp.com>
2015-01-21 16:04:08 +00:00
rpcrdma_free_regbuf(ia, req->rl_sendbuf);
rpcrdma_free_regbuf(ia, req->rl_rdmabuf);
kfree(req);
}
void
rpcrdma_buffer_destroy(struct rpcrdma_buffer *buf)
{
struct rpcrdma_ia *ia = rdmab_to_ia(buf);
while (!list_empty(&buf->rb_recv_bufs)) {
struct rpcrdma_rep *rep;
rep = rpcrdma_buffer_get_rep_locked(buf);
rpcrdma_destroy_rep(ia, rep);
}
spin_lock(&buf->rb_reqslock);
while (!list_empty(&buf->rb_allreqs)) {
struct rpcrdma_req *req;
nfs-rdma: Fix for FMR leaks Two memory region leaks were found during testing: 1. rpcrdma_buffer_create: While allocating RPCRDMA_FRMR's ib_alloc_fast_reg_mr is called and then ib_alloc_fast_reg_page_list is called. If ib_alloc_fast_reg_page_list returns an error it bails out of the routine dropping the last ib_alloc_fast_reg_mr frmr region creating a memory leak. Added code to dereg the last frmr if ib_alloc_fast_reg_page_list fails. 2. rpcrdma_buffer_destroy: While cleaning up, the routine will only free the MR's on the rb_mws list if there are rb_send_bufs present. However, in rpcrdma_buffer_create while the rb_mws list is being built if one of the MR allocation requests fail after some MR's have been allocated on the rb_mws list the routine never gets to create any rb_send_bufs but instead jumps to the rpcrdma_buffer_destroy routine which will never free the MR's on rb_mws list because the rb_send_bufs were never created. This leaks all the MR's on the rb_mws list that were created prior to one of the MR allocations failing. Issue(2) was seen during testing. Our adapter had a finite number of MR's available and we created enough connections to where we saw an MR allocation failure on our Nth NFS connection request. After the kernel cleaned up the resources it had allocated for the Nth connection we noticed that FMR's had been leaked due to the coding error described above. Issue(1) was seen during a code review while debugging issue(2). Signed-off-by: Allen Andrews <allen.andrews@emulex.com> Reviewed-by: Chuck Lever <chuck.lever@oracle.com> Signed-off-by: Anna Schumaker <Anna.Schumaker@Netapp.com>
2014-05-28 14:32:09 +00:00
req = list_first_entry(&buf->rb_allreqs,
struct rpcrdma_req, rl_all);
list_del(&req->rl_all);
spin_unlock(&buf->rb_reqslock);
rpcrdma_destroy_req(ia, req);
spin_lock(&buf->rb_reqslock);
}
spin_unlock(&buf->rb_reqslock);
nfs-rdma: Fix for FMR leaks Two memory region leaks were found during testing: 1. rpcrdma_buffer_create: While allocating RPCRDMA_FRMR's ib_alloc_fast_reg_mr is called and then ib_alloc_fast_reg_page_list is called. If ib_alloc_fast_reg_page_list returns an error it bails out of the routine dropping the last ib_alloc_fast_reg_mr frmr region creating a memory leak. Added code to dereg the last frmr if ib_alloc_fast_reg_page_list fails. 2. rpcrdma_buffer_destroy: While cleaning up, the routine will only free the MR's on the rb_mws list if there are rb_send_bufs present. However, in rpcrdma_buffer_create while the rb_mws list is being built if one of the MR allocation requests fail after some MR's have been allocated on the rb_mws list the routine never gets to create any rb_send_bufs but instead jumps to the rpcrdma_buffer_destroy routine which will never free the MR's on rb_mws list because the rb_send_bufs were never created. This leaks all the MR's on the rb_mws list that were created prior to one of the MR allocations failing. Issue(2) was seen during testing. Our adapter had a finite number of MR's available and we created enough connections to where we saw an MR allocation failure on our Nth NFS connection request. After the kernel cleaned up the resources it had allocated for the Nth connection we noticed that FMR's had been leaked due to the coding error described above. Issue(1) was seen during a code review while debugging issue(2). Signed-off-by: Allen Andrews <allen.andrews@emulex.com> Reviewed-by: Chuck Lever <chuck.lever@oracle.com> Signed-off-by: Anna Schumaker <Anna.Schumaker@Netapp.com>
2014-05-28 14:32:09 +00:00
ia->ri_ops->ro_destroy(buf);
}
struct rpcrdma_mw *
rpcrdma_get_mw(struct rpcrdma_xprt *r_xprt)
{
struct rpcrdma_buffer *buf = &r_xprt->rx_buf;
struct rpcrdma_mw *mw = NULL;
spin_lock(&buf->rb_mwlock);
if (!list_empty(&buf->rb_mws)) {
mw = list_first_entry(&buf->rb_mws,
struct rpcrdma_mw, mw_list);
list_del_init(&mw->mw_list);
}
spin_unlock(&buf->rb_mwlock);
if (!mw)
pr_err("RPC: %s: no MWs available\n", __func__);
return mw;
}
void
rpcrdma_put_mw(struct rpcrdma_xprt *r_xprt, struct rpcrdma_mw *mw)
{
struct rpcrdma_buffer *buf = &r_xprt->rx_buf;
spin_lock(&buf->rb_mwlock);
list_add_tail(&mw->mw_list, &buf->rb_mws);
spin_unlock(&buf->rb_mwlock);
}
/*
* Get a set of request/reply buffers.
*
* Reply buffer (if available) is attached to send buffer upon return.
*/
struct rpcrdma_req *
rpcrdma_buffer_get(struct rpcrdma_buffer *buffers)
{
struct rpcrdma_req *req;
spin_lock(&buffers->rb_lock);
if (list_empty(&buffers->rb_send_bufs))
goto out_reqbuf;
req = rpcrdma_buffer_get_req_locked(buffers);
if (list_empty(&buffers->rb_recv_bufs))
goto out_repbuf;
req->rl_reply = rpcrdma_buffer_get_rep_locked(buffers);
spin_unlock(&buffers->rb_lock);
return req;
out_reqbuf:
spin_unlock(&buffers->rb_lock);
pr_warn("RPC: %s: out of request buffers\n", __func__);
return NULL;
out_repbuf:
spin_unlock(&buffers->rb_lock);
pr_warn("RPC: %s: out of reply buffers\n", __func__);
req->rl_reply = NULL;
return req;
}
/*
* Put request/reply buffers back into pool.
* Pre-decrement counter/array index.
*/
void
rpcrdma_buffer_put(struct rpcrdma_req *req)
{
struct rpcrdma_buffer *buffers = req->rl_buffer;
struct rpcrdma_rep *rep = req->rl_reply;
req->rl_niovs = 0;
req->rl_reply = NULL;
spin_lock(&buffers->rb_lock);
list_add_tail(&req->rl_free, &buffers->rb_send_bufs);
if (rep)
list_add_tail(&rep->rr_list, &buffers->rb_recv_bufs);
spin_unlock(&buffers->rb_lock);
}
/*
* Recover reply buffers from pool.
* This happens when recovering from disconnect.
*/
void
rpcrdma_recv_buffer_get(struct rpcrdma_req *req)
{
struct rpcrdma_buffer *buffers = req->rl_buffer;
spin_lock(&buffers->rb_lock);
if (!list_empty(&buffers->rb_recv_bufs))
req->rl_reply = rpcrdma_buffer_get_rep_locked(buffers);
spin_unlock(&buffers->rb_lock);
}
/*
* Put reply buffers back into pool when not attached to
* request. This happens in error conditions.
*/
void
rpcrdma_recv_buffer_put(struct rpcrdma_rep *rep)
{
struct rpcrdma_buffer *buffers = &rep->rr_rxprt->rx_buf;
spin_lock(&buffers->rb_lock);
list_add_tail(&rep->rr_list, &buffers->rb_recv_bufs);
spin_unlock(&buffers->rb_lock);
}
/*
* Wrappers for internal-use kmalloc memory registration, used by buffer code.
*/
void
rpcrdma_mapping_error(struct rpcrdma_mr_seg *seg)
{
dprintk("RPC: map_one: offset %p iova %llx len %zu\n",
seg->mr_offset,
(unsigned long long)seg->mr_dma, seg->mr_dmalen);
}
/**
* rpcrdma_alloc_regbuf - kmalloc and register memory for SEND/RECV buffers
* @ia: controlling rpcrdma_ia
* @size: size of buffer to be allocated, in bytes
* @flags: GFP flags
*
* Returns pointer to private header of an area of internally
* registered memory, or an ERR_PTR. The registered buffer follows
* the end of the private header.
*
* xprtrdma uses a regbuf for posting an outgoing RDMA SEND, or for
* receiving the payload of RDMA RECV operations. regbufs are not
* used for RDMA READ/WRITE operations, thus are registered only for
* LOCAL access.
*/
struct rpcrdma_regbuf *
rpcrdma_alloc_regbuf(struct rpcrdma_ia *ia, size_t size, gfp_t flags)
{
struct rpcrdma_regbuf *rb;
struct ib_sge *iov;
rb = kmalloc(sizeof(*rb) + size, flags);
if (rb == NULL)
goto out;
iov = &rb->rg_iov;
iov->addr = ib_dma_map_single(ia->ri_device,
(void *)rb->rg_base, size,
DMA_BIDIRECTIONAL);
if (ib_dma_mapping_error(ia->ri_device, iov->addr))
goto out_free;
iov->length = size;
iov->lkey = ia->ri_pd->local_dma_lkey;
rb->rg_size = size;
rb->rg_owner = NULL;
return rb;
out_free:
kfree(rb);
out:
return ERR_PTR(-ENOMEM);
}
/**
* rpcrdma_free_regbuf - deregister and free registered buffer
* @ia: controlling rpcrdma_ia
* @rb: regbuf to be deregistered and freed
*/
void
rpcrdma_free_regbuf(struct rpcrdma_ia *ia, struct rpcrdma_regbuf *rb)
{
struct ib_sge *iov;
if (!rb)
return;
iov = &rb->rg_iov;
ib_dma_unmap_single(ia->ri_device,
iov->addr, iov->length, DMA_BIDIRECTIONAL);
kfree(rb);
}
/*
* Prepost any receive buffer, then post send.
*
* Receive buffer is donated to hardware, reclaimed upon recv completion.
*/
int
rpcrdma_ep_post(struct rpcrdma_ia *ia,
struct rpcrdma_ep *ep,
struct rpcrdma_req *req)
{
struct ib_device *device = ia->ri_device;
struct ib_send_wr send_wr, *send_wr_fail;
struct rpcrdma_rep *rep = req->rl_reply;
struct ib_sge *iov = req->rl_send_iov;
int i, rc;
if (rep) {
rc = rpcrdma_ep_post_recv(ia, ep, rep);
if (rc)
goto out;
req->rl_reply = NULL;
}
send_wr.next = NULL;
send_wr.wr_id = RPCRDMA_IGNORE_COMPLETION;
send_wr.sg_list = iov;
send_wr.num_sge = req->rl_niovs;
send_wr.opcode = IB_WR_SEND;
for (i = 0; i < send_wr.num_sge; i++)
ib_dma_sync_single_for_device(device, iov[i].addr,
iov[i].length, DMA_TO_DEVICE);
dprintk("RPC: %s: posting %d s/g entries\n",
__func__, send_wr.num_sge);
if (DECR_CQCOUNT(ep) > 0)
send_wr.send_flags = 0;
else { /* Provider must take a send completion every now and then */
INIT_CQCOUNT(ep);
send_wr.send_flags = IB_SEND_SIGNALED;
}
rc = ib_post_send(ia->ri_id->qp, &send_wr, &send_wr_fail);
if (rc)
dprintk("RPC: %s: ib_post_send returned %i\n", __func__,
rc);
out:
return rc;
}
/*
* (Re)post a receive buffer.
*/
int
rpcrdma_ep_post_recv(struct rpcrdma_ia *ia,
struct rpcrdma_ep *ep,
struct rpcrdma_rep *rep)
{
struct ib_recv_wr recv_wr, *recv_wr_fail;
int rc;
recv_wr.next = NULL;
recv_wr.wr_id = (u64) (unsigned long) rep;
recv_wr.sg_list = &rep->rr_rdmabuf->rg_iov;
recv_wr.num_sge = 1;
ib_dma_sync_single_for_cpu(ia->ri_device,
rdmab_addr(rep->rr_rdmabuf),
rdmab_length(rep->rr_rdmabuf),
DMA_BIDIRECTIONAL);
rc = ib_post_recv(ia->ri_id->qp, &recv_wr, &recv_wr_fail);
if (rc)
dprintk("RPC: %s: ib_post_recv returned %i\n", __func__,
rc);
return rc;
}
/**
* rpcrdma_ep_post_extra_recv - Post buffers for incoming backchannel requests
* @r_xprt: transport associated with these backchannel resources
* @min_reqs: minimum number of incoming requests expected
*
* Returns zero if all requested buffers were posted, or a negative errno.
*/
int
rpcrdma_ep_post_extra_recv(struct rpcrdma_xprt *r_xprt, unsigned int count)
{
struct rpcrdma_buffer *buffers = &r_xprt->rx_buf;
struct rpcrdma_ia *ia = &r_xprt->rx_ia;
struct rpcrdma_ep *ep = &r_xprt->rx_ep;
struct rpcrdma_rep *rep;
unsigned long flags;
int rc;
while (count--) {
spin_lock_irqsave(&buffers->rb_lock, flags);
if (list_empty(&buffers->rb_recv_bufs))
goto out_reqbuf;
rep = rpcrdma_buffer_get_rep_locked(buffers);
spin_unlock_irqrestore(&buffers->rb_lock, flags);
rc = rpcrdma_ep_post_recv(ia, ep, rep);
if (rc)
goto out_rc;
}
return 0;
out_reqbuf:
spin_unlock_irqrestore(&buffers->rb_lock, flags);
pr_warn("%s: no extra receive buffers\n", __func__);
return -ENOMEM;
out_rc:
rpcrdma_recv_buffer_put(rep);
return rc;
}
/* How many chunk list items fit within our inline buffers?
*/
unsigned int
rpcrdma_max_segments(struct rpcrdma_xprt *r_xprt)
{
struct rpcrdma_create_data_internal *cdata = &r_xprt->rx_data;
int bytes, segments;
bytes = min_t(unsigned int, cdata->inline_wsize, cdata->inline_rsize);
bytes -= RPCRDMA_HDRLEN_MIN;
if (bytes < sizeof(struct rpcrdma_segment) * 2) {
pr_warn("RPC: %s: inline threshold too small\n",
__func__);
return 0;
}
segments = 1 << (fls(bytes / sizeof(struct rpcrdma_segment)) - 1);
dprintk("RPC: %s: max chunk list size = %d segments\n",
__func__, segments);
return segments;
}