OpenSolaris_b135/lib/udapl/udapl_tavor/common/dapl_ep_modify.c
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright (c) 2002-2003, Network Appliance, Inc. All rights reserved.
*/
/*
* Copyright 2007 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
/*
*
* MODULE: dapl_ep_modify.c
*
* PURPOSE: Endpoint management
* Description: Interfaces in this file are completely described in
* the DAPL 1.0 API, Chapter 6, section 5
*
* $Id: dapl_ep_modify.c,v 1.23 2003/07/11 18:42:17 hobie16 Exp $
*/
#include "dapl.h"
#include "dapl_cookie.h"
#include "dapl_ep_util.h"
#include "dapl_adapter_util.h"
/*
* Internal prototypes
*/
static _INLINE_ DAT_RETURN
dapli_ep_modify_validate_parameters(
IN DAT_EP_HANDLE ep_handle,
IN DAT_EP_PARAM_MASK ep_param_mask,
IN const DAT_EP_PARAM *ep_param,
OUT DAPL_IA **ia_ptr,
OUT DAPL_EP **ep_ptr,
OUT DAT_EP_ATTR *ep_attr_ptr);
/*
* dapl_ep_modify
*
* DAPL Requirements Version xxx, 6.5.6
*
* Provide the consumer parameters, including attributes and status of
* the Endpoint.
*
* Input:
* ep_handle
* ep_args_mask
*
* Output:
* ep_args
*
* Returns:
* DAT_SUCCESS
* DAT_INVALID_PARAMETER
* DAT_INVALID_ATTRIBUTE
* DAT_INVALID_STATE
*/
DAT_RETURN
dapl_ep_modify(
IN DAT_EP_HANDLE ep_handle,
IN DAT_EP_PARAM_MASK ep_param_mask,
IN const DAT_EP_PARAM *ep_param)
{
DAPL_IA *ia;
DAPL_EP *ep1, *ep2;
DAT_EP_ATTR ep_attr1, ep_attr2;
DAPL_EP new_ep, copy_of_old_ep;
DAPL_EP alloc_ep; /* Holder for resources. */
DAPL_PZ *tmp_pz;
DAPL_EVD *tmp_evd;
DAT_RETURN dat_status;
/* Flag indicating we've allocated a new one of these. */
DAT_BOOLEAN qp_allocated = DAT_FALSE;
DAT_BOOLEAN rqst_cb_allocated = DAT_FALSE;
DAT_BOOLEAN recv_cb_allocated = DAT_FALSE;
/* Flag indicating we've used (assigned to QP) a new one of these. */
DAT_BOOLEAN qp_used = DAT_FALSE;
DAT_BOOLEAN rqst_cb_used = DAT_FALSE;
DAT_BOOLEAN recv_cb_used = DAT_FALSE;
dat_status = dapli_ep_modify_validate_parameters(ep_handle,
ep_param_mask, ep_param, &ia, &ep1, &ep_attr1);
if (DAT_SUCCESS != dat_status) {
goto bail;
}
/*
* Setup the alloc_ep with the appropriate parameters (primarily
* for allocating the QP.
*/
alloc_ep = *ep1;
alloc_ep.param.ep_attr = ep_attr1;
if (ep_param_mask & DAT_EP_FIELD_PZ_HANDLE) {
alloc_ep.param.pz_handle = ep_param->pz_handle;
}
if (ep_param_mask & DAT_EP_FIELD_RECV_EVD_HANDLE) {
alloc_ep.param.recv_evd_handle = ep_param->recv_evd_handle;
}
if (ep_param_mask & DAT_EP_FIELD_REQUEST_EVD_HANDLE) {
alloc_ep.param.request_evd_handle =
ep_param->request_evd_handle;
}
if (ep_param_mask & DAT_EP_FIELD_CONNECT_EVD_HANDLE) {
alloc_ep.param.connect_evd_handle =
ep_param->connect_evd_handle;
}
/*
* Allocate everything that might be needed.
* We allocate separately, and into a different "holding"
* ep, since we a) want the copy of the old ep into the new ep to
* be atomic with the assignment back (under lock), b) want the
* assignment of the allocated materials to be after the copy of the
* old ep into the new ep, and c) don't want the allocation done
* under lock.
*/
dat_status = dapls_cb_create(
&alloc_ep.req_buffer, ep1, DAPL_COOKIE_QUEUE_EP,
ep_attr1.max_request_dtos);
if (DAT_SUCCESS != dat_status) {
goto bail;
}
rqst_cb_allocated = DAT_TRUE;
if (!ep1->srq_attached) {
dat_status = dapls_cb_create(&alloc_ep.recv_buffer, ep1,
DAPL_COOKIE_QUEUE_EP, ep_attr1.max_recv_dtos);
if (DAT_SUCCESS != dat_status) {
goto bail;
}
recv_cb_allocated = DAT_TRUE;
}
dat_status = dapls_ib_qp_alloc(ia, &alloc_ep, ep1);
if (dat_status != DAT_SUCCESS) {
goto bail;
}
qp_allocated = DAT_TRUE;
/*
* Now we atomically modify the EP, under lock
* There's a lot of work done here, but there should be no
* allocation or blocking.
*/
dapl_os_lock(&ep1->header.lock);
/*
* Revalidate parameters; make sure that races haven't
* changed anything important.
*/
dat_status = dapli_ep_modify_validate_parameters(ep_handle,
ep_param_mask, ep_param, &ia, &ep2, &ep_attr2);
if (DAT_SUCCESS != dat_status) {
dapl_os_unlock(&ep2->header.lock);
goto bail;
}
/*
* All of the following should be impossible, if validation
* occurred. But they're important to the logic of this routine,
* so we check.
*/
dapl_os_assert(ep1 == ep2);
dapl_os_assert(ep_attr2.max_recv_dtos == ep_attr1.max_recv_dtos);
dapl_os_assert(ep_attr2.max_request_dtos == ep_attr1.max_request_dtos);
copy_of_old_ep = *ep2;
/*
* Setup new ep.
*/
new_ep = *ep2;
new_ep.param.ep_attr = ep_attr2;
/*
* We can initialize the PZ and EVD handles from the alloc_ep because
* the only thing that could have changed since we setup the alloc_ep
* is stuff changed by dapl_cr_accept, and neither PZ nor EVD is in that
* list.
*/
new_ep.param.pz_handle = alloc_ep.param.pz_handle;
new_ep.param.recv_evd_handle = alloc_ep.param.recv_evd_handle;
new_ep.param.request_evd_handle = alloc_ep.param.request_evd_handle;
new_ep.param.connect_evd_handle = alloc_ep.param.connect_evd_handle;
/* Deal with each of the allocation fields. */
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_RECV_DTOS &&
(ep_param->ep_attr.max_recv_dtos !=
ep2->param.ep_attr.max_recv_dtos)) {
new_ep.recv_buffer = alloc_ep.recv_buffer;
recv_cb_used = DAT_TRUE;
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_DTOS &&
(ep_param->ep_attr.max_request_dtos !=
ep2->param.ep_attr.max_request_dtos)) {
new_ep.req_buffer = alloc_ep.req_buffer;
rqst_cb_used = DAT_TRUE;
}
/*
* We need to change the QP only if there already was a QP
* (leave things the way you found them!) and one of the
* following has changed: send/recv EVD, send/recv reqs/IOV max.
*/
if (DAPL_QP_STATE_UNATTACHED != new_ep.qp_state && (ep_param_mask
& (DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_IOV |
DAT_EP_FIELD_EP_ATTR_MAX_RECV_IOV |
DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_DTOS |
DAT_EP_FIELD_EP_ATTR_MAX_RECV_DTOS |
DAT_EP_FIELD_RECV_EVD_HANDLE |
DAT_EP_FIELD_REQUEST_EVD_HANDLE))) {
/*
* We shouldn't be racing with connection establishment
* because the parameter validate routine should protect us,
* but it's an important enough point that we assert it.
*/
dapl_os_assert((ep2->param.ep_state !=
DAT_EP_STATE_PASSIVE_CONNECTION_PENDING) &&
(ep2->param.ep_state !=
DAT_EP_STATE_ACTIVE_CONNECTION_PENDING));
new_ep.qp_handle = alloc_ep.qp_handle;
new_ep.qpn = alloc_ep.qpn;
qp_used = DAT_TRUE;
}
/*
* The actual assignment, including modifying QP parameters.
* Modifying QP parameters needs to come first, as if it fails
* we need to exit.
*/
if (DAPL_QP_STATE_UNATTACHED != new_ep.qp_state) {
dat_status = dapls_ib_qp_modify(ia, ep2, &ep_attr2);
if (dat_status != DAT_SUCCESS) {
dapl_os_unlock(& ep2->header.lock);
goto bail;
}
}
*ep2 = new_ep;
dapl_os_unlock(&ep2->header.lock);
/*
* Modify reference counts, incrementing new ones
* and then decrementing old ones (so if they're the same
* the refcount never drops to zero).
*/
tmp_pz = (DAPL_PZ *) new_ep.param.pz_handle;
if (NULL != tmp_pz) {
dapl_os_atomic_inc(&tmp_pz->pz_ref_count);
}
tmp_evd = (DAPL_EVD *) new_ep.param.recv_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_inc(&tmp_evd->evd_ref_count);
}
tmp_evd = (DAPL_EVD *) new_ep.param.request_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_inc(&tmp_evd->evd_ref_count);
}
tmp_evd = (DAPL_EVD *) new_ep.param.connect_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_inc(&tmp_evd->evd_ref_count);
}
/* decreament the old reference counts */
tmp_pz = (DAPL_PZ *) copy_of_old_ep.param.pz_handle;
if (NULL != tmp_pz) {
dapl_os_atomic_dec(&tmp_pz->pz_ref_count);
}
tmp_evd = (DAPL_EVD *) copy_of_old_ep.param.recv_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_dec(&tmp_evd->evd_ref_count);
}
tmp_evd = (DAPL_EVD *) copy_of_old_ep.param.request_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_dec(&tmp_evd->evd_ref_count);
}
tmp_evd = (DAPL_EVD *) copy_of_old_ep.param.connect_evd_handle;
if (NULL != tmp_evd) {
dapl_os_atomic_dec(&tmp_evd->evd_ref_count);
}
bail:
if (qp_allocated) {
DAT_RETURN local_dat_status;
if (dat_status != DAT_SUCCESS || !qp_used) {
local_dat_status = dapls_ib_qp_free(ia, &alloc_ep);
} else {
local_dat_status = dapls_ib_qp_free(ia,
©_of_old_ep);
}
if (local_dat_status != DAT_SUCCESS) {
dapl_dbg_log(DAPL_DBG_TYPE_WARN,
"ep_modify: Failed to free QP; status %x\n",
local_dat_status);
}
}
if (rqst_cb_allocated) {
if (dat_status != DAT_SUCCESS || !rqst_cb_used) {
dapls_cb_free(&alloc_ep.req_buffer);
} else {
dapls_cb_free(©_of_old_ep.req_buffer);
}
}
if (recv_cb_allocated) {
if (dat_status != DAT_SUCCESS || !recv_cb_used) {
dapls_cb_free(&alloc_ep.recv_buffer);
} else {
dapls_cb_free(©_of_old_ep.recv_buffer);
}
}
return (dat_status);
}
/*
* dapli_ep_modify_validate_parameters
*
* Validate parameters
*
* The space for the ep_attr_ptr parameter should be allocated by the
* consumer. Upon success, this parameter will contain the current ep
* attribute values with the requested modifications made.
*
*/
static DAT_RETURN
dapli_ep_modify_validate_parameters(
IN DAT_EP_HANDLE ep_handle,
IN DAT_EP_PARAM_MASK ep_param_mask,
IN const DAT_EP_PARAM *ep_param,
OUT DAPL_IA **ia_ptr,
OUT DAPL_EP **ep_ptr,
OUT DAT_EP_ATTR *ep_attr_ptr)
{
DAPL_IA *ia;
DAPL_EP *ep;
DAT_EP_ATTR ep_attr;
DAT_EP_ATTR ep_attr_limit;
DAT_EP_ATTR ep_attr_request;
DAT_RETURN dat_status;
*ia_ptr = NULL;
*ep_ptr = NULL;
dat_status = DAT_SUCCESS;
if (DAPL_BAD_HANDLE(ep_handle, DAPL_MAGIC_EP)) {
dat_status = DAT_ERROR(DAT_INVALID_HANDLE,
DAT_INVALID_HANDLE_EP);
goto bail;
}
ep = (DAPL_EP *) ep_handle;
ia = ep->header.owner_ia;
/*
* Verify parameters valid in current EP state
*/
if (ep_param_mask & (DAT_EP_FIELD_IA_HANDLE |
DAT_EP_FIELD_EP_STATE |
DAT_EP_FIELD_LOCAL_IA_ADDRESS_PTR |
DAT_EP_FIELD_LOCAL_PORT_QUAL |
DAT_EP_FIELD_REMOTE_IA_ADDRESS_PTR |
DAT_EP_FIELD_REMOTE_PORT_QUAL |
DAT_EP_FIELD_SRQ_HANDLE |
DAT_EP_FIELD_EP_ATTR_SRQ_SOFT_HW)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER, DAT_INVALID_ARG2);
goto bail;
}
/*
* Can only change the PZ handle if we are UNCONNECTED or
* TENTATIVE_CONNECTION_PENDING(psp PROVIDER allocated EP)
*/
if ((ep_param_mask & DAT_EP_FIELD_PZ_HANDLE) &&
(ep->param.ep_state != DAT_EP_STATE_UNCONNECTED &&
ep->param.ep_state !=
DAT_EP_STATE_TENTATIVE_CONNECTION_PENDING)) {
dat_status = DAT_ERROR(DAT_INVALID_STATE,
dapls_ep_state_subtype(ep));
goto bail;
}
if ((ep_param_mask & (DAT_EP_FIELD_RECV_EVD_HANDLE |
DAT_EP_FIELD_REQUEST_EVD_HANDLE |
DAT_EP_FIELD_CONNECT_EVD_HANDLE |
DAT_EP_FIELD_EP_ATTR_SERVICE_TYPE |
DAT_EP_FIELD_EP_ATTR_MAX_MESSAGE_SIZE |
DAT_EP_FIELD_EP_ATTR_MAX_RDMA_SIZE |
DAT_EP_FIELD_EP_ATTR_QOS |
DAT_EP_FIELD_EP_ATTR_REQUEST_COMPLETION_FLAGS |
DAT_EP_FIELD_EP_ATTR_RECV_COMPLETION_FLAGS |
DAT_EP_FIELD_EP_ATTR_MAX_RECV_DTOS |
DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_DTOS |
DAT_EP_FIELD_EP_ATTR_MAX_RECV_IOV |
DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_IOV)) &&
(ep->param.ep_state != DAT_EP_STATE_UNCONNECTED &&
ep->param.ep_state != DAT_EP_STATE_RESERVED &&
ep->param.ep_state !=
DAT_EP_STATE_TENTATIVE_CONNECTION_PENDING)) {
dat_status = DAT_ERROR(DAT_INVALID_STATE,
dapls_ep_state_subtype(ep));
goto bail;
}
/*
* Validate handles being modified
*/
if (ep_param_mask & DAT_EP_FIELD_PZ_HANDLE) {
if (ep_param->pz_handle != NULL &&
DAPL_BAD_HANDLE(ep_param->pz_handle, DAPL_MAGIC_PZ)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
}
}
if (ep_param_mask & DAT_EP_FIELD_RECV_EVD_HANDLE) {
if (ep_param->recv_evd_handle != NULL &&
(DAPL_BAD_HANDLE(ep_param->recv_evd_handle,
DAPL_MAGIC_EVD) ||
!((DAPL_EVD *)ep_param->recv_evd_handle)->evd_flags &
DAT_EVD_DTO_FLAG)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
}
}
if (ep_param_mask & DAT_EP_FIELD_REQUEST_EVD_HANDLE) {
if (ep_param->request_evd_handle != NULL &&
DAPL_BAD_HANDLE(ep_param->request_evd_handle,
DAPL_MAGIC_EVD)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
}
}
if (ep_param_mask & DAT_EP_FIELD_CONNECT_EVD_HANDLE) {
if (ep_param->connect_evd_handle != NULL &&
DAPL_BAD_HANDLE(ep_param->connect_evd_handle,
DAPL_MAGIC_EVD) &&
!(((DAPL_EVD *)ep_param->connect_evd_handle)->evd_flags &
DAT_EVD_CONNECTION_FLAG)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
}
}
/*
* Validate the attributes against the HCA limits
*/
ep_attr = ep->param.ep_attr;
(void) dapl_os_memzero(&ep_attr_limit, sizeof (DAT_EP_ATTR));
dat_status = dapls_ib_query_hca(ia->hca_ptr, NULL,
&ep_attr_limit, NULL, NULL);
if (dat_status != DAT_SUCCESS) {
goto bail;
}
ep_attr_request = ep_param->ep_attr;
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_SERVICE_TYPE) {
if (ep_attr_request.service_type != DAT_SERVICE_TYPE_RC) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_MESSAGE_SIZE) {
if (ep_attr_request.max_mtu_size > ep_attr_limit.max_mtu_size) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
} else {
ep_attr.max_mtu_size = ep_attr_request.max_mtu_size;
}
}
/*
* Do nothing if the DAT_EP_FIELD_EP_ATTR_MAX_RDMA_SIZE flag is
* set. Each RDMA transport/provider may or may not have a limit
* on the size of an RDMA DTO. For InfiniBand, this parameter is
* validated in the implementation of the dapls_ib_qp_modify()
* function.
*/
/* LINTED: E_NOP_IF_STMT */
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_QOS) {
/* Do nothing, not defined in the spec yet */
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_RECV_COMPLETION_FLAGS) {
dat_status = dapl_ep_check_recv_completion_flags(
ep_attr_request.recv_completion_flags);
if (dat_status != DAT_SUCCESS) {
goto bail;
} else {
ep_attr.recv_completion_flags =
ep_attr_request.recv_completion_flags;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_REQUEST_COMPLETION_FLAGS) {
dat_status = dapl_ep_check_request_completion_flags(
ep_attr_request.request_completion_flags);
if (dat_status != DAT_SUCCESS) {
goto bail;
} else {
ep_attr.request_completion_flags =
ep_attr_request.request_completion_flags;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_RECV_DTOS) {
if ((ep->param.srq_handle != NULL) ||
(ep_attr_request.max_recv_dtos >
ep_attr_limit.max_recv_dtos) ||
(ep_param->recv_evd_handle == DAT_HANDLE_NULL &&
(ep_attr_request.max_recv_dtos > 0))) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
} else {
ep_attr.max_recv_dtos = ep_attr_request.max_recv_dtos;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_DTOS) {
if (ep_attr_request.max_request_dtos >
ep_attr_limit.max_request_dtos ||
(ep_param->request_evd_handle == DAT_HANDLE_NULL &&
(ep_attr_request.max_request_dtos > 0))) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
} else {
ep_attr.max_request_dtos =
ep_attr_request.max_request_dtos;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_RECV_IOV) {
if ((ep->param.srq_handle != NULL) ||
(ep_attr_request.max_recv_iov >
ep_attr_limit.max_recv_iov)) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
} else {
ep_attr.max_recv_iov = ep_attr_request.max_recv_iov;
}
}
if (ep_param_mask & DAT_EP_FIELD_EP_ATTR_MAX_REQUEST_IOV) {
if (ep_attr_request.max_request_iov >
ep_attr_limit.max_request_iov) {
dat_status = DAT_ERROR(DAT_INVALID_PARAMETER,
DAT_INVALID_ARG3);
goto bail;
} else {
ep_attr.max_request_iov =
ep_attr_request.max_request_iov;
}
}
*ia_ptr = ia;
*ep_ptr = ep;
*ep_attr_ptr = ep_attr;
bail:
return (dat_status);
}