freebsd-skq/sys/dev/ocs_fc/ocs_els.c
Kenneth D. Merry ef270ab1b6 Bring in the Broadcom/Emulex Fibre Channel driver, ocs_fc(4).
The ocs_fc(4) driver supports the following hardware:

Emulex 16/8G FC GEN 5 HBAS
	LPe15004 FC Host Bus Adapters
	LPe160XX FC Host Bus Adapters

Emulex 32/16G FC GEN 6 HBAS
	LPe3100X FC Host Bus Adapters
	LPe3200X FC Host Bus Adapters

The driver supports target and initiator mode, and also supports FC-Tape.

Note that the driver only currently works on little endian platforms.  It
is only included in the module build for amd64 and i386, and in GENERIC
on amd64 only.

Submitted by:	Ram Kishore Vegesna <ram.vegesna@broadcom.com>
Reviewed by:	mav
MFC after:	5 days
Relnotes:	yes
Sponsored by:	Broadcom
Differential Revision:	https://reviews.freebsd.org/D11423
2018-03-30 15:28:25 +00:00

2778 lines
73 KiB
C

/*-
* Copyright (c) 2017 Broadcom. All rights reserved.
* The term "Broadcom" refers to Broadcom Limited and/or its subsidiaries.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 HOLDER 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.
*
* $FreeBSD$
*/
/**
* @file
* Functions to build and send ELS/CT/BLS commands and responses.
*/
/*!
@defgroup els_api ELS/BLS/CT Command and Response Functions
*/
#include "ocs.h"
#include "ocs_els.h"
#include "ocs_scsi.h"
#include "ocs_device.h"
#define ELS_IOFMT "[i:%04x t:%04x h:%04x]"
#define ELS_IOFMT_ARGS(els) els->init_task_tag, els->tgt_task_tag, els->hw_tag
#define node_els_trace() \
do { \
if (OCS_LOG_ENABLE_ELS_TRACE(ocs)) \
ocs_log_info(ocs, "[%s] %-20s\n", node->display_name, __func__); \
} while (0)
#define els_io_printf(els, fmt, ...) \
ocs_log_debug(els->node->ocs, "[%s]" ELS_IOFMT " %-8s " fmt, els->node->display_name, ELS_IOFMT_ARGS(els), els->display_name, ##__VA_ARGS__);
static int32_t ocs_els_send(ocs_io_t *els, uint32_t reqlen, uint32_t timeout_sec, ocs_hw_srrs_cb_t cb);
static int32_t ocs_els_send_rsp(ocs_io_t *els, uint32_t rsplen);
static int32_t ocs_els_acc_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *arg);
static ocs_io_t *ocs_bls_send_acc(ocs_io_t *io, uint32_t s_id, uint16_t ox_id, uint16_t rx_id);
static int32_t ocs_bls_send_acc_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length,
int32_t status, uint32_t ext_status, void *app);
static void ocs_io_transition(ocs_io_t *els, ocs_sm_function_t state, void *data);
static ocs_io_t *ocs_els_abort_io(ocs_io_t *els, int send_abts);
static void _ocs_els_io_free(void *arg);
static void ocs_els_delay_timer_cb(void *arg);
/**
* @ingroup els_api
* @brief ELS state machine transition wrapper.
*
* <h3 class="desc">Description</h3>
* This function is the transition wrapper for the ELS state machine. It grabs
* the node lock prior to making the transition to protect
* against multiple threads accessing a particular ELS. For example,
* one thread transitioning from __els_init to
* __ocs_els_wait_resp and another thread (tasklet) handling the
* completion of that ELS request.
*
* @param els Pointer to the IO context.
* @param state State to transition to.
* @param data Data to pass in with the transition.
*
* @return None.
*/
static void
ocs_io_transition(ocs_io_t *els, ocs_sm_function_t state, void *data)
{
/* protect ELS events with node lock */
ocs_node_t *node = els->node;
ocs_node_lock(node);
ocs_sm_transition(&els->els_sm, state, data);
ocs_node_unlock(node);
}
/**
* @ingroup els_api
* @brief ELS state machine post event wrapper.
*
* <h3 class="desc">Description</h3>
* Post an event wrapper for the ELS state machine. This function grabs
* the node lock prior to posting the event.
*
* @param els Pointer to the IO context.
* @param evt Event to process.
* @param data Data to pass in with the transition.
*
* @return None.
*/
void
ocs_els_post_event(ocs_io_t *els, ocs_sm_event_t evt, void *data)
{
/* protect ELS events with node lock */
ocs_node_t *node = els->node;
ocs_node_lock(node);
els->els_evtdepth ++;
ocs_sm_post_event(&els->els_sm, evt, data);
els->els_evtdepth --;
ocs_node_unlock(node);
if (els->els_evtdepth == 0 && els->els_req_free) {
ocs_els_io_free(els);
}
}
/**
* @ingroup els_api
* @brief Allocate an IO structure for an ELS IO context.
*
* <h3 class="desc">Description</h3>
* Allocate an IO for an ELS context. Uses OCS_ELS_RSP_LEN as response size.
*
* @param node node to associate ELS IO with
* @param reqlen Length of ELS request
* @param role Role of ELS (originator/responder)
*
* @return pointer to IO structure allocated
*/
ocs_io_t *
ocs_els_io_alloc(ocs_node_t *node, uint32_t reqlen, ocs_els_role_e role)
{
return ocs_els_io_alloc_size(node, reqlen, OCS_ELS_RSP_LEN, role);
}
/**
* @ingroup els_api
* @brief Allocate an IO structure for an ELS IO context.
*
* <h3 class="desc">Description</h3>
* Allocate an IO for an ELS context, allowing the caller to specify the size of the response.
*
* @param node node to associate ELS IO with
* @param reqlen Length of ELS request
* @param rsplen Length of ELS response
* @param role Role of ELS (originator/responder)
*
* @return pointer to IO structure allocated
*/
ocs_io_t *
ocs_els_io_alloc_size(ocs_node_t *node, uint32_t reqlen, uint32_t rsplen, ocs_els_role_e role)
{
ocs_t *ocs;
ocs_xport_t *xport;
ocs_io_t *els;
ocs_assert(node, NULL);
ocs_assert(node->ocs, NULL);
ocs = node->ocs;
ocs_assert(ocs->xport, NULL);
xport = ocs->xport;
ocs_lock(&node->active_ios_lock);
if (!node->io_alloc_enabled) {
ocs_log_debug(ocs, "called with io_alloc_enabled = FALSE\n");
ocs_unlock(&node->active_ios_lock);
return NULL;
}
els = ocs_io_alloc(ocs);
if (els == NULL) {
ocs_atomic_add_return(&xport->io_alloc_failed_count, 1);
ocs_unlock(&node->active_ios_lock);
return NULL;
}
/* initialize refcount */
ocs_ref_init(&els->ref, _ocs_els_io_free, els);
switch (role) {
case OCS_ELS_ROLE_ORIGINATOR:
els->cmd_ini = TRUE;
els->cmd_tgt = FALSE;
break;
case OCS_ELS_ROLE_RESPONDER:
els->cmd_ini = FALSE;
els->cmd_tgt = TRUE;
break;
}
/* IO should not have an associated HW IO yet. Assigned below. */
if (els->hio != NULL) {
ocs_log_err(ocs, "assertion failed. HIO is not null\n");
ocs_io_free(ocs, els);
ocs_unlock(&node->active_ios_lock);
return NULL;
}
/* populate generic io fields */
els->ocs = ocs;
els->node = node;
/* set type and ELS-specific fields */
els->io_type = OCS_IO_TYPE_ELS;
els->display_name = "pending";
if (reqlen > OCS_ELS_REQ_LEN) {
ocs_log_err(ocs, "ELS command request len greater than allocated\n");
ocs_io_free(ocs, els);
ocs_unlock(&node->active_ios_lock);
return NULL;
}
if (rsplen > OCS_ELS_GID_PT_RSP_LEN) {
ocs_log_err(ocs, "ELS command response len: %d "
"greater than allocated\n", rsplen);
ocs_io_free(ocs, els);
ocs_unlock(&node->active_ios_lock);
return NULL;
}
els->els_req.size = reqlen;
els->els_rsp.size = rsplen;
if (els != NULL) {
ocs_memset(&els->els_sm, 0, sizeof(els->els_sm));
els->els_sm.app = els;
/* initialize fields */
els->els_retries_remaining = OCS_FC_ELS_DEFAULT_RETRIES;
els->els_evtdepth = 0;
els->els_pend = 0;
els->els_active = 0;
/* add els structure to ELS IO list */
ocs_list_add_tail(&node->els_io_pend_list, els);
els->els_pend = 1;
}
ocs_unlock(&node->active_ios_lock);
return els;
}
/**
* @ingroup els_api
* @brief Free IO structure for an ELS IO context.
*
* <h3 class="desc">Description</h3> Free IO for an ELS
* IO context
*
* @param els ELS IO structure for which IO is allocated
*
* @return None
*/
void
ocs_els_io_free(ocs_io_t *els)
{
ocs_ref_put(&els->ref);
}
/**
* @ingroup els_api
* @brief Free IO structure for an ELS IO context.
*
* <h3 class="desc">Description</h3> Free IO for an ELS
* IO context
*
* @param arg ELS IO structure for which IO is allocated
*
* @return None
*/
static void
_ocs_els_io_free(void *arg)
{
ocs_io_t *els = (ocs_io_t *)arg;
ocs_t *ocs;
ocs_node_t *node;
int send_empty_event = FALSE;
ocs_assert(els);
ocs_assert(els->node);
ocs_assert(els->node->ocs);
ocs = els->node->ocs;
node = els->node;
ocs = node->ocs;
ocs_lock(&node->active_ios_lock);
if (els->els_active) {
/* if active, remove from active list and check empty */
ocs_list_remove(&node->els_io_active_list, els);
/* Send list empty event if the IO allocator is disabled, and the list is empty
* If node->io_alloc_enabled was not checked, the event would be posted continually
*/
send_empty_event = (!node->io_alloc_enabled) && ocs_list_empty(&node->els_io_active_list);
els->els_active = 0;
} else if (els->els_pend) {
/* if pending, remove from pending list; node shutdown isn't
* gated off the pending list (only the active list), so no
* need to check if pending list is empty
*/
ocs_list_remove(&node->els_io_pend_list, els);
els->els_pend = 0;
} else {
ocs_log_err(ocs, "assertion failed: niether els->els_pend nor els->active set\n");
ocs_unlock(&node->active_ios_lock);
return;
}
ocs_unlock(&node->active_ios_lock);
ocs_io_free(ocs, els);
if (send_empty_event) {
ocs_node_post_event(node, OCS_EVT_ALL_CHILD_NODES_FREE, NULL);
}
ocs_scsi_check_pending(ocs);
}
/**
* @ingroup els_api
* @brief Make ELS IO active
*
* @param els Pointer to the IO context to make active.
*
* @return Returns 0 on success; or a negative error code value on failure.
*/
static void
ocs_els_make_active(ocs_io_t *els)
{
ocs_node_t *node = els->node;
/* move ELS from pending list to active list */
ocs_lock(&node->active_ios_lock);
if (els->els_pend) {
if (els->els_active) {
ocs_log_err(node->ocs, "assertion failed: both els->els_pend and els->active set\n");
ocs_unlock(&node->active_ios_lock);
return;
} else {
/* remove from pending list */
ocs_list_remove(&node->els_io_pend_list, els);
els->els_pend = 0;
/* add els structure to ELS IO list */
ocs_list_add_tail(&node->els_io_active_list, els);
els->els_active = 1;
}
} else {
/* must be retrying; make sure it's already active */
if (!els->els_active) {
ocs_log_err(node->ocs, "assertion failed: niether els->els_pend nor els->active set\n");
}
}
ocs_unlock(&node->active_ios_lock);
}
/**
* @ingroup els_api
* @brief Send the ELS command.
*
* <h3 class="desc">Description</h3>
* The command, given by the \c els IO context, is sent to the node that the IO was
* configured with, using ocs_hw_srrs_send(). Upon completion,
* the \c cb callback is invoked,
* with the application-specific argument set to the \c els IO context.
*
* @param els Pointer to the IO context.
* @param reqlen Byte count in the payload to send.
* @param timeout_sec Command timeout, in seconds (0 -> 2*R_A_TOV).
* @param cb Completion callback.
*
* @return Returns 0 on success; or a negative error code value on failure.
*/
static int32_t
ocs_els_send(ocs_io_t *els, uint32_t reqlen, uint32_t timeout_sec, ocs_hw_srrs_cb_t cb)
{
ocs_node_t *node = els->node;
/* update ELS request counter */
node->els_req_cnt++;
/* move ELS from pending list to active list */
ocs_els_make_active(els);
els->wire_len = reqlen;
return ocs_scsi_io_dispatch(els, cb);
}
/**
* @ingroup els_api
* @brief Send the ELS response.
*
* <h3 class="desc">Description</h3>
* The ELS response, given by the \c els IO context, is sent to the node
* that the IO was configured with, using ocs_hw_srrs_send().
*
* @param els Pointer to the IO context.
* @param rsplen Byte count in the payload to send.
*
* @return Returns 0 on success; or a negative error value on failure.
*/
static int32_t
ocs_els_send_rsp(ocs_io_t *els, uint32_t rsplen)
{
ocs_node_t *node = els->node;
/* increment ELS completion counter */
node->els_cmpl_cnt++;
/* move ELS from pending list to active list */
ocs_els_make_active(els);
els->wire_len = rsplen;
return ocs_scsi_io_dispatch(els, ocs_els_acc_cb);
}
/**
* @ingroup els_api
* @brief Handle ELS IO request completions.
*
* <h3 class="desc">Description</h3>
* This callback is used for several ELS send operations.
*
* @param hio Pointer to the HW IO context that completed.
* @param rnode Pointer to the remote node.
* @param length Length of the returned payload data.
* @param status Status of the completion.
* @param ext_status Extended status of the completion.
* @param arg Application-specific argument (generally a pointer to the ELS IO context).
*
* @return Returns 0 on success; or a negative error value on failure.
*/
static int32_t
ocs_els_req_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *arg)
{
ocs_io_t *els;
ocs_node_t *node;
ocs_t *ocs;
ocs_node_cb_t cbdata;
ocs_io_t *io;
ocs_assert(arg, -1);
io = arg;
els = io;
ocs_assert(els, -1);
ocs_assert(els->node, -1);
node = els->node;
ocs_assert(node->ocs, -1);
ocs = node->ocs;
ocs_assert(io->hio, -1);
ocs_assert(hio == io->hio, -1);
if (status != 0) {
els_io_printf(els, "status x%x ext x%x\n", status, ext_status);
}
/* set the response len element of els->rsp */
els->els_rsp.len = length;
cbdata.status = status;
cbdata.ext_status = ext_status;
cbdata.header = NULL;
cbdata.els = els;
/* FW returns the number of bytes received on the link in
* the WCQE, not the amount placed in the buffer; use this info to
* check if there was an overrun.
*/
if (length > els->els_rsp.size) {
ocs_log_warn(ocs, "ELS response returned len=%d > buflen=%zu\n",
length, els->els_rsp.size);
ocs_els_post_event(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &cbdata);
return 0;
}
/* Post event to ELS IO object */
switch (status) {
case SLI4_FC_WCQE_STATUS_SUCCESS:
ocs_els_post_event(els, OCS_EVT_SRRS_ELS_REQ_OK, &cbdata);
break;
case SLI4_FC_WCQE_STATUS_LS_RJT:
ocs_els_post_event(els, OCS_EVT_SRRS_ELS_REQ_RJT, &cbdata);
break;
case SLI4_FC_WCQE_STATUS_LOCAL_REJECT:
switch (ext_status) {
case SLI4_FC_LOCAL_REJECT_SEQUENCE_TIMEOUT:
ocs_els_post_event(els, OCS_EVT_ELS_REQ_TIMEOUT, &cbdata);
break;
case SLI4_FC_LOCAL_REJECT_ABORT_REQUESTED:
ocs_els_post_event(els, OCS_EVT_ELS_REQ_ABORTED, &cbdata);
break;
default:
ocs_els_post_event(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &cbdata);
break;
}
break;
default:
ocs_log_warn(ocs, "els req complete: failed status x%x, ext_status, x%x\n", status, ext_status);
ocs_els_post_event(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &cbdata);
break;
}
return 0;
}
/**
* @ingroup els_api
* @brief Handle ELS IO accept/response completions.
*
* <h3 class="desc">Description</h3>
* This callback is used for several ELS send operations.
*
* @param hio Pointer to the HW IO context that completed.
* @param rnode Pointer to the remote node.
* @param length Length of the returned payload data.
* @param status Status of the completion.
* @param ext_status Extended status of the completion.
* @param arg Application-specific argument (generally a pointer to the ELS IO context).
*
* @return Returns 0 on success; or a negative error value on failure.
*/
static int32_t
ocs_els_acc_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *arg)
{
ocs_io_t *els;
ocs_node_t *node;
ocs_t *ocs;
ocs_node_cb_t cbdata;
ocs_io_t *io;
ocs_assert(arg, -1);
io = arg;
els = io;
ocs_assert(els, -1);
ocs_assert(els->node, -1);
node = els->node;
ocs_assert(node->ocs, -1);
ocs = node->ocs;
ocs_assert(io->hio, -1);
ocs_assert(hio == io->hio, -1);
cbdata.status = status;
cbdata.ext_status = ext_status;
cbdata.header = NULL;
cbdata.els = els;
/* Post node event */
switch (status) {
case SLI4_FC_WCQE_STATUS_SUCCESS:
ocs_node_post_event(node, OCS_EVT_SRRS_ELS_CMPL_OK, &cbdata);
break;
default:
ocs_log_warn(ocs, "[%s] %-8s failed status x%x, ext_status x%x\n",
node->display_name, els->display_name, status, ext_status);
ocs_log_warn(ocs, "els acc complete: failed status x%x, ext_status, x%x\n", status, ext_status);
ocs_node_post_event(node, OCS_EVT_SRRS_ELS_CMPL_FAIL, &cbdata);
break;
}
/* If this IO has a callback, invoke it */
if (els->els_callback) {
(*els->els_callback)(node, &cbdata, els->els_callback_arg);
}
ocs_els_io_free(els);
return 0;
}
/**
* @ingroup els_api
* @brief Format and send a PLOGI ELS command.
*
* <h3 class="desc">Description</h3>
* Construct a PLOGI payload using the domain SLI port service parameters,
* and send to the \c node.
*
* @param node Node to which the PLOGI is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_plogi(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
void (*cb)(ocs_node_t *node, ocs_node_cb_t *cbdata, void *arg), void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fc_plogi_payload_t *plogi;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*plogi), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "plogi";
/* Build PLOGI request */
plogi = els->els_req.virt;
ocs_memcpy(plogi, node->sport->service_params, sizeof(*plogi));
plogi->command_code = FC_ELS_CMD_PLOGI;
plogi->resv1 = 0;
ocs_display_sparams(node->display_name, "plogi send req", 0, NULL, plogi->common_service_parameters);
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Format and send a FLOGI ELS command.
*
* <h3 class="desc">Description</h3>
* Construct an FLOGI payload, and send to the \c node.
*
* @param node Node to which the FLOGI is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_flogi(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs;
fc_plogi_payload_t *flogi;
ocs_assert(node, NULL);
ocs_assert(node->ocs, NULL);
ocs_assert(node->sport, NULL);
ocs = node->ocs;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*flogi), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "flogi";
/* Build FLOGI request */
flogi = els->els_req.virt;
ocs_memcpy(flogi, node->sport->service_params, sizeof(*flogi));
flogi->command_code = FC_ELS_CMD_FLOGI;
flogi->resv1 = 0;
/* Priority tagging support */
flogi->common_service_parameters[1] |= ocs_htobe32(1U << 23);
ocs_display_sparams(node->display_name, "flogi send req", 0, NULL, flogi->common_service_parameters);
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Format and send a FDISC ELS command.
*
* <h3 class="desc">Description</h3>
* Construct an FDISC payload, and send to the \c node.
*
* @param node Node to which the FDISC is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_fdisc(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs;
fc_plogi_payload_t *fdisc;
ocs_assert(node, NULL);
ocs_assert(node->ocs, NULL);
ocs = node->ocs;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*fdisc), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "fdisc";
/* Build FDISC request */
fdisc = els->els_req.virt;
ocs_memcpy(fdisc, node->sport->service_params, sizeof(*fdisc));
fdisc->command_code = FC_ELS_CMD_FDISC;
fdisc->resv1 = 0;
ocs_display_sparams(node->display_name, "fdisc send req", 0, NULL, fdisc->common_service_parameters);
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a PRLI ELS command.
*
* <h3 class="desc">Description</h3>
* Construct a PRLI ELS command, and send to the \c node.
*
* @param node Node to which the PRLI is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_prli(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_t *ocs = node->ocs;
ocs_io_t *els;
fc_prli_payload_t *prli;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*prli), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "prli";
/* Build PRLI request */
prli = els->els_req.virt;
ocs_memset(prli, 0, sizeof(*prli));
prli->command_code = FC_ELS_CMD_PRLI;
prli->page_length = 16;
prli->payload_length = ocs_htobe16(sizeof(fc_prli_payload_t));
prli->type = FC_TYPE_FCP;
prli->type_ext = 0;
prli->flags = ocs_htobe16(FC_PRLI_ESTABLISH_IMAGE_PAIR);
prli->service_params = ocs_htobe16(FC_PRLI_READ_XRDY_DISABLED |
(node->sport->enable_ini ? FC_PRLI_INITIATOR_FUNCTION : 0) |
(node->sport->enable_tgt ? FC_PRLI_TARGET_FUNCTION : 0));
/* For Tape Drive support */
prli->service_params |= ocs_htobe16(FC_PRLI_CONFIRMED_COMPLETION | FC_PRLI_RETRY |
FC_PRLI_TASK_RETRY_ID_REQ| FC_PRLI_REC_SUPPORT);
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a PRLO ELS command.
*
* <h3 class="desc">Description</h3>
* Construct a PRLO ELS command, and send to the \c node.
*
* @param node Node to which the PRLO is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_prlo(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_t *ocs = node->ocs;
ocs_io_t *els;
fc_prlo_payload_t *prlo;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*prlo), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "prlo";
/* Build PRLO request */
prlo = els->els_req.virt;
ocs_memset(prlo, 0, sizeof(*prlo));
prlo->command_code = FC_ELS_CMD_PRLO;
prlo->page_length = 16;
prlo->payload_length = ocs_htobe16(sizeof(fc_prlo_payload_t));
prlo->type = FC_TYPE_FCP;
prlo->type_ext = 0;
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a LOGO ELS command.
*
* <h3 class="desc">Description</h3>
* Format a LOGO, and send to the \c node.
*
* @param node Node to which the LOGO is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_logo(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs;
fc_logo_payload_t *logo;
fc_plogi_payload_t *sparams;
ocs = node->ocs;
node_els_trace();
sparams = (fc_plogi_payload_t*) node->sport->service_params;
els = ocs_els_io_alloc(node, sizeof(*logo), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "logo";
/* Build LOGO request */
logo = els->els_req.virt;
ocs_memset(logo, 0, sizeof(*logo));
logo->command_code = FC_ELS_CMD_LOGO;
logo->resv1 = 0;
logo->port_id = fc_htobe24(node->rnode.sport->fc_id);
logo->port_name_hi = sparams->port_name_hi;
logo->port_name_lo = sparams->port_name_lo;
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send an ADISC ELS command.
*
* <h3 class="desc">Description</h3>
* Construct an ADISC ELS command, and send to the \c node.
*
* @param node Node to which the ADISC is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_adisc(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs;
fc_adisc_payload_t *adisc;
fc_plogi_payload_t *sparams;
ocs_sport_t *sport = node->sport;
ocs = node->ocs;
node_els_trace();
sparams = (fc_plogi_payload_t*) node->sport->service_params;
els = ocs_els_io_alloc(node, sizeof(*adisc), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "adisc";
/* Build ADISC request */
adisc = els->els_req.virt;
sparams = (fc_plogi_payload_t*) node->sport->service_params;
ocs_memset(adisc, 0, sizeof(*adisc));
adisc->command_code = FC_ELS_CMD_ADISC;
adisc->hard_address = fc_htobe24(sport->fc_id);
adisc->port_name_hi = sparams->port_name_hi;
adisc->port_name_lo = sparams->port_name_lo;
adisc->node_name_hi = sparams->node_name_hi;
adisc->node_name_lo = sparams->node_name_lo;
adisc->port_id = fc_htobe24(node->rnode.sport->fc_id);
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a PDISC ELS command.
*
* <h3 class="desc">Description</h3>
* Construct a PDISC ELS command, and send to the \c node.
*
* @param node Node to which the PDISC is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_pdisc(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fc_plogi_payload_t *pdisc;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*pdisc), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "pdisc";
pdisc = els->els_req.virt;
ocs_memcpy(pdisc, node->sport->service_params, sizeof(*pdisc));
pdisc->command_code = FC_ELS_CMD_PDISC;
pdisc->resv1 = 0;
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send an SCR ELS command.
*
* <h3 class="desc">Description</h3>
* Format an SCR, and send to the \c node.
*
* @param node Node to which the SCR is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function
* @param cbarg Callback function arg
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_scr(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fc_scr_payload_t *req;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*req), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "scr";
req = els->els_req.virt;
ocs_memset(req, 0, sizeof(*req));
req->command_code = FC_ELS_CMD_SCR;
req->function = FC_SCR_REG_FULL;
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send an RRQ ELS command.
*
* <h3 class="desc">Description</h3>
* Format an RRQ, and send to the \c node.
*
* @param node Node to which the RRQ is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function
* @param cbarg Callback function arg
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_rrq(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fc_scr_payload_t *req;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*req), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "scr";
req = els->els_req.virt;
ocs_memset(req, 0, sizeof(*req));
req->command_code = FC_ELS_CMD_RRQ;
req->function = FC_SCR_REG_FULL;
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send an RSCN ELS command.
*
* <h3 class="desc">Description</h3>
* Format an RSCN, and send to the \c node.
*
* @param node Node to which the RRQ is sent.
* @param timeout_sec Command timeout, in seconds.
* @param retries Number of times to retry errors before reporting a failure.
* @param port_ids Pointer to port IDs
* @param port_ids_count Count of port IDs
* @param cb Callback function
* @param cbarg Callback function arg
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_rscn(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
void *port_ids, uint32_t port_ids_count, els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fc_rscn_payload_t *req;
uint32_t payload_length = sizeof(fc_rscn_affected_port_id_page_t)*(port_ids_count - 1) +
sizeof(fc_rscn_payload_t);
node_els_trace();
els = ocs_els_io_alloc(node, payload_length, OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->els_timeout_sec = timeout_sec;
els->els_retries_remaining = retries;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "rscn";
req = els->els_req.virt;
req->command_code = FC_ELS_CMD_RSCN;
req->page_length = sizeof(fc_rscn_affected_port_id_page_t);
req->payload_length = ocs_htobe16(sizeof(*req) +
sizeof(fc_rscn_affected_port_id_page_t)*(port_ids_count-1));
els->hio_type = OCS_HW_ELS_REQ;
els->iparam.els.timeout = timeout_sec;
/* copy in the payload */
ocs_memcpy(req->port_list, port_ids, port_ids_count*sizeof(fc_rscn_affected_port_id_page_t));
/* Submit the request */
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @brief Send an LS_RJT ELS response.
*
* <h3 class="desc">Description</h3>
* Send an LS_RJT ELS response.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID being responded to.
* @param reason_code Reason code value for LS_RJT.
* @param reason_code_expl Reason code explanation value for LS_RJT.
* @param vendor_unique Vendor-unique value for LS_RJT.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_ls_rjt(ocs_io_t *io, uint32_t ox_id, uint32_t reason_code, uint32_t reason_code_expl,
uint32_t vendor_unique, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_ls_rjt_payload_t *rjt;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "ls_rjt";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
rjt = io->els_req.virt;
ocs_memset(rjt, 0, sizeof(*rjt));
rjt->command_code = FC_ELS_CMD_RJT;
rjt->reason_code = reason_code;
rjt->reason_code_exp = reason_code_expl;
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*rjt)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a PLOGI accept response.
*
* <h3 class="desc">Description</h3>
* Construct a PLOGI LS_ACC, and send to the \c node, using the originator exchange ID
* \c ox_id.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID being responsed to.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_plogi_acc(ocs_io_t *io, uint32_t ox_id, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_plogi_payload_t *plogi;
fc_plogi_payload_t *req = (fc_plogi_payload_t *)node->service_params;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "plog_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
plogi = io->els_req.virt;
/* copy our port's service parameters to payload */
ocs_memcpy(plogi, node->sport->service_params, sizeof(*plogi));
plogi->command_code = FC_ELS_CMD_ACC;
plogi->resv1 = 0;
/* Set Application header support bit if requested */
if (req->common_service_parameters[1] & ocs_htobe32(1U << 24)) {
plogi->common_service_parameters[1] |= ocs_htobe32(1U << 24);
}
/* Priority tagging support. */
if (req->common_service_parameters[1] & ocs_htobe32(1U << 23)) {
plogi->common_service_parameters[1] |= ocs_htobe32(1U << 23);
}
ocs_display_sparams(node->display_name, "plogi send resp", 0, NULL, plogi->common_service_parameters);
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*plogi)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send an FLOGI accept response for point-to-point negotiation.
*
* <h3 class="desc">Description</h3>
* Construct an FLOGI accept response, and send to the \c node using the originator
* exchange id \c ox_id. The \c s_id is used for the response frame source FC ID.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID for the response.
* @param s_id Source FC ID to be used in the response frame.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_flogi_p2p_acc(ocs_io_t *io, uint32_t ox_id, uint32_t s_id, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_plogi_payload_t *flogi;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "flogi_p2p_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els_sid.ox_id = ox_id;
io->iparam.els_sid.s_id = s_id;
flogi = io->els_req.virt;
/* copy our port's service parameters to payload */
ocs_memcpy(flogi, node->sport->service_params, sizeof(*flogi));
flogi->command_code = FC_ELS_CMD_ACC;
flogi->resv1 = 0;
ocs_memset(flogi->class1_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class2_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class3_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class4_service_parameters, 0, sizeof(flogi->class1_service_parameters));
io->hio_type = OCS_HW_ELS_RSP_SID;
if ((rc = ocs_els_send_rsp(io, sizeof(*flogi)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
ocs_io_t *
ocs_send_flogi_acc(ocs_io_t *io, uint32_t ox_id, uint32_t is_fport, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_plogi_payload_t *flogi;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "flogi_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els_sid.ox_id = ox_id;
io->iparam.els_sid.s_id = io->node->sport->fc_id;
flogi = io->els_req.virt;
/* copy our port's service parameters to payload */
ocs_memcpy(flogi, node->sport->service_params, sizeof(*flogi));
/* Set F_port */
if (is_fport) {
/* Set F_PORT and Multiple N_PORT_ID Assignment */
flogi->common_service_parameters[1] |= ocs_be32toh(3U << 28);
}
flogi->command_code = FC_ELS_CMD_ACC;
flogi->resv1 = 0;
ocs_display_sparams(node->display_name, "flogi send resp", 0, NULL, flogi->common_service_parameters);
ocs_memset(flogi->class1_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class2_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class3_service_parameters, 0, sizeof(flogi->class1_service_parameters));
ocs_memset(flogi->class4_service_parameters, 0, sizeof(flogi->class1_service_parameters));
io->hio_type = OCS_HW_ELS_RSP_SID;
if ((rc = ocs_els_send_rsp(io, sizeof(*flogi)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a PRLI accept response
*
* <h3 class="desc">Description</h3>
* Construct a PRLI LS_ACC response, and send to the \c node, using the originator
* \c ox_id exchange ID.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_prli_acc(ocs_io_t *io, uint32_t ox_id, uint8_t fc_type, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_prli_payload_t *prli;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "prli_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
prli = io->els_req.virt;
ocs_memset(prli, 0, sizeof(*prli));
prli->command_code = FC_ELS_CMD_ACC;
prli->page_length = 16;
prli->payload_length = ocs_htobe16(sizeof(fc_prli_payload_t));
prli->type = fc_type;
prli->type_ext = 0;
prli->flags = ocs_htobe16(FC_PRLI_ESTABLISH_IMAGE_PAIR | FC_PRLI_REQUEST_EXECUTED);
prli->service_params = ocs_htobe16(FC_PRLI_READ_XRDY_DISABLED |
(node->sport->enable_ini ? FC_PRLI_INITIATOR_FUNCTION : 0) |
(node->sport->enable_tgt ? FC_PRLI_TARGET_FUNCTION : 0));
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*prli)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a PRLO accept response.
*
* <h3 class="desc">Description</h3>
* Construct a PRLO LS_ACC response, and send to the \c node, using the originator
* exchange ID \c ox_id.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_prlo_acc(ocs_io_t *io, uint32_t ox_id, uint8_t fc_type, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_prlo_acc_payload_t *prlo_acc;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "prlo_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
prlo_acc = io->els_req.virt;
ocs_memset(prlo_acc, 0, sizeof(*prlo_acc));
prlo_acc->command_code = FC_ELS_CMD_ACC;
prlo_acc->page_length = 16;
prlo_acc->payload_length = ocs_htobe16(sizeof(fc_prlo_acc_payload_t));
prlo_acc->type = fc_type;
prlo_acc->type_ext = 0;
prlo_acc->response_code = FC_PRLO_REQUEST_EXECUTED;
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*prlo_acc)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a generic LS_ACC response without a payload.
*
* <h3 class="desc">Description</h3>
* A generic LS_ACC response is sent to the \c node using the originator exchange ID
* \c ox_id.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange id.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_ls_acc(ocs_io_t *io, uint32_t ox_id, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_acc_payload_t *acc;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "ls_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
acc = io->els_req.virt;
ocs_memset(acc, 0, sizeof(*acc));
acc->command_code = FC_ELS_CMD_ACC;
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*acc)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a LOGO accept response.
*
* <h3 class="desc">Description</h3>
* Construct a LOGO LS_ACC response, and send to the \c node, using the originator
* exchange ID \c ox_id.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_logo_acc(ocs_io_t *io, uint32_t ox_id, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
ocs_t *ocs = node->ocs;
fc_acc_payload_t *logo;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "logo_acc";
io->init_task_tag = ox_id;
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
logo = io->els_req.virt;
ocs_memset(logo, 0, sizeof(*logo));
logo->command_code = FC_ELS_CMD_ACC;
logo->resv1 = 0;
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*logo)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send an ADISC accept response.
*
* <h3 class="desc">Description</h3>
* Construct an ADISC LS__ACC, and send to the \c node, using the originator
* exchange id \c ox_id.
*
* @param io Pointer to a SCSI IO object.
* @param ox_id Originator exchange ID.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_send_adisc_acc(ocs_io_t *io, uint32_t ox_id, els_cb_t cb, void *cbarg)
{
ocs_node_t *node = io->node;
int32_t rc;
fc_adisc_payload_t *adisc;
fc_plogi_payload_t *sparams;
ocs_t *ocs;
ocs_assert(node, NULL);
ocs_assert(node->ocs, NULL);
ocs = node->ocs;
node_els_trace();
io->els_callback = cb;
io->els_callback_arg = cbarg;
io->display_name = "adisc_acc";
io->init_task_tag = ox_id;
/* Go ahead and send the ELS_ACC */
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.els.ox_id = ox_id;
sparams = (fc_plogi_payload_t*) node->sport->service_params;
adisc = io->els_req.virt;
ocs_memset(adisc, 0, sizeof(fc_adisc_payload_t));
adisc->command_code = FC_ELS_CMD_ACC;
adisc->hard_address = 0;
adisc->port_name_hi = sparams->port_name_hi;
adisc->port_name_lo = sparams->port_name_lo;
adisc->node_name_hi = sparams->node_name_hi;
adisc->node_name_lo = sparams->node_name_lo;
adisc->port_id = fc_htobe24(node->rnode.sport->fc_id);
io->hio_type = OCS_HW_ELS_RSP;
if ((rc = ocs_els_send_rsp(io, sizeof(*adisc)))) {
ocs_els_io_free(io);
io = NULL;
}
return io;
}
/**
* @ingroup els_api
* @brief Send a RFTID CT request.
*
* <h3 class="desc">Description</h3>
* Construct an RFTID CT request, and send to the \c node.
*
* @param node Node to which the RFTID request is sent.
* @param timeout_sec Time, in seconds, to wait before timing out the ELS.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_ns_send_rftid(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fcct_rftid_req_t *rftid;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*rftid), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->iparam.fc_ct.r_ctl = FC_RCTL_ELS;
els->iparam.fc_ct.type = FC_TYPE_GS;
els->iparam.fc_ct.df_ctl = 0;
els->iparam.fc_ct.timeout = timeout_sec;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "rftid";
rftid = els->els_req.virt;
ocs_memset(rftid, 0, sizeof(*rftid));
fcct_build_req_header(&rftid->hdr, FC_GS_NAMESERVER_RFT_ID, (OCS_ELS_RSP_LEN - sizeof(rftid->hdr)));
rftid->port_id = ocs_htobe32(node->rnode.sport->fc_id);
rftid->fc4_types[FC_GS_TYPE_WORD(FC_TYPE_FCP)] = ocs_htobe32(1 << FC_GS_TYPE_BIT(FC_TYPE_FCP));
els->hio_type = OCS_HW_FC_CT;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a RFFID CT request.
*
* <h3 class="desc">Description</h3>
* Construct an RFFID CT request, and send to the \c node.
*
* @param node Node to which the RFFID request is sent.
* @param timeout_sec Time, in seconds, to wait before timing out the ELS.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_ns_send_rffid(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fcct_rffid_req_t *rffid;
node_els_trace();
els = ocs_els_io_alloc(node, sizeof(*rffid), OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->iparam.fc_ct.r_ctl = FC_RCTL_ELS;
els->iparam.fc_ct.type = FC_TYPE_GS;
els->iparam.fc_ct.df_ctl = 0;
els->iparam.fc_ct.timeout = timeout_sec;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "rffid";
rffid = els->els_req.virt;
ocs_memset(rffid, 0, sizeof(*rffid));
fcct_build_req_header(&rffid->hdr, FC_GS_NAMESERVER_RFF_ID, (OCS_ELS_RSP_LEN - sizeof(rffid->hdr)));
rffid->port_id = ocs_htobe32(node->rnode.sport->fc_id);
if (node->sport->enable_ini) {
rffid->fc4_feature_bits |= FC4_FEATURE_INITIATOR;
}
if (node->sport->enable_tgt) {
rffid->fc4_feature_bits |= FC4_FEATURE_TARGET;
}
rffid->type = FC_TYPE_FCP;
els->hio_type = OCS_HW_FC_CT;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a GIDPT CT request.
*
* <h3 class="desc">Description</h3>
* Construct a GIDPT CT request, and send to the \c node.
*
* @param node Node to which the GIDPT request is sent.
* @param timeout_sec Time, in seconds, to wait before timing out the ELS.
* @param retries Number of times to retry errors before reporting a failure.
* @param cb Callback function.
* @param cbarg Callback function argument.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_ns_send_gidpt(ocs_node_t *node, uint32_t timeout_sec, uint32_t retries,
els_cb_t cb, void *cbarg)
{
ocs_io_t *els;
ocs_t *ocs = node->ocs;
fcct_gidpt_req_t *gidpt;
node_els_trace();
els = ocs_els_io_alloc_size(node, sizeof(*gidpt), OCS_ELS_GID_PT_RSP_LEN, OCS_ELS_ROLE_ORIGINATOR);
if (els == NULL) {
ocs_log_err(ocs, "IO alloc failed\n");
} else {
els->iparam.fc_ct.r_ctl = FC_RCTL_ELS;
els->iparam.fc_ct.type = FC_TYPE_GS;
els->iparam.fc_ct.df_ctl = 0;
els->iparam.fc_ct.timeout = timeout_sec;
els->els_callback = cb;
els->els_callback_arg = cbarg;
els->display_name = "gidpt";
gidpt = els->els_req.virt;
ocs_memset(gidpt, 0, sizeof(*gidpt));
fcct_build_req_header(&gidpt->hdr, FC_GS_NAMESERVER_GID_PT, (OCS_ELS_GID_PT_RSP_LEN - sizeof(gidpt->hdr)) );
gidpt->domain_id_scope = 0;
gidpt->area_id_scope = 0;
gidpt->port_type = 0x7f;
els->hio_type = OCS_HW_FC_CT;
ocs_io_transition(els, __ocs_els_init, NULL);
}
return els;
}
/**
* @ingroup els_api
* @brief Send a BA_ACC given the request's FC header
*
* <h3 class="desc">Description</h3>
* Using the S_ID/D_ID from the request's FC header, generate a BA_ACC.
*
* @param io Pointer to a SCSI IO object.
* @param hdr Pointer to the FC header.
*
* @return Returns pointer to IO object, or NULL if error.
*/
ocs_io_t *
ocs_bls_send_acc_hdr(ocs_io_t *io, fc_header_t *hdr)
{
uint16_t ox_id = ocs_be16toh(hdr->ox_id);
uint16_t rx_id = ocs_be16toh(hdr->rx_id);
uint32_t d_id = fc_be24toh(hdr->d_id);
return ocs_bls_send_acc(io, d_id, ox_id, rx_id);
}
/**
* @ingroup els_api
* @brief Send a BLS BA_ACC response.
*
* <h3 class="desc">Description</h3>
* Construct a BLS BA_ACC response, and send to the \c node.
*
* @param io Pointer to a SCSI IO object.
* @param s_id S_ID to use for the response. If UINT32_MAX, then use our SLI port
* (sport) S_ID.
* @param ox_id Originator exchange ID.
* @param rx_id Responder exchange ID.
*
* @return Returns pointer to IO object, or NULL if error.
*/
static ocs_io_t *
ocs_bls_send_acc(ocs_io_t *io, uint32_t s_id, uint16_t ox_id, uint16_t rx_id)
{
ocs_node_t *node = io->node;
int32_t rc;
fc_ba_acc_payload_t *acc;
ocs_t *ocs;
ocs_assert(node, NULL);
ocs_assert(node->ocs, NULL);
ocs = node->ocs;
if (node->rnode.sport->fc_id == s_id) {
s_id = UINT32_MAX;
}
/* fill out generic fields */
io->ocs = ocs;
io->node = node;
io->cmd_tgt = TRUE;
/* fill out BLS Response-specific fields */
io->io_type = OCS_IO_TYPE_BLS_RESP;
io->display_name = "ba_acc";
io->hio_type = OCS_HW_BLS_ACC_SID;
io->init_task_tag = ox_id;
/* fill out iparam fields */
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->iparam.bls_sid.s_id = s_id;
io->iparam.bls_sid.ox_id = ox_id;
io->iparam.bls_sid.rx_id = rx_id;
acc = (void *)io->iparam.bls_sid.payload;
ocs_memset(io->iparam.bls_sid.payload, 0, sizeof(io->iparam.bls_sid.payload));
acc->ox_id = io->iparam.bls_sid.ox_id;
acc->rx_id = io->iparam.bls_sid.rx_id;
acc->high_seq_cnt = UINT16_MAX;
if ((rc = ocs_scsi_io_dispatch(io, ocs_bls_send_acc_cb))) {
ocs_log_err(ocs, "ocs_scsi_io_dispatch() failed: %d\n", rc);
ocs_scsi_io_free(io);
io = NULL;
}
return io;
}
/**
* @brief Handle the BLS accept completion.
*
* <h3 class="desc">Description</h3>
* Upon completion of sending a BA_ACC, this callback is invoked by the HW.
*
* @param hio Pointer to the HW IO object.
* @param rnode Pointer to the HW remote node.
* @param length Length of the response payload, in bytes.
* @param status Completion status.
* @param ext_status Extended completion status.
* @param app Callback private argument.
*
* @return Returns 0 on success; or a negative error value on failure.
*/
static int32_t
ocs_bls_send_acc_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *app)
{
ocs_io_t *io = app;
ocs_assert(io, -1);
ocs_scsi_io_free(io);
return 0;
}
/**
* @brief ELS abort callback.
*
* <h3 class="desc">Description</h3>
* This callback is invoked by the HW when an ELS IO is aborted.
*
* @param hio Pointer to the HW IO object.
* @param rnode Pointer to the HW remote node.
* @param length Length of the response payload, in bytes.
* @param status Completion status.
* @param ext_status Extended completion status.
* @param app Callback private argument.
*
* @return Returns 0 on success; or a negative error value on failure.
*/
static int32_t
ocs_els_abort_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *app)
{
ocs_io_t *els;
ocs_io_t *abort_io = NULL; /* IO structure used to abort ELS */
ocs_t *ocs;
ocs_assert(app, -1);
abort_io = app;
els = abort_io->io_to_abort;
ocs_assert(els->node, -1);
ocs_assert(els->node->ocs, -1);
ocs = els->node->ocs;
if (status != 0) {
ocs_log_warn(ocs, "status x%x ext x%x\n", status, ext_status);
}
/* now free the abort IO */
ocs_io_free(ocs, abort_io);
/* send completion event to indicate abort process is complete
* Note: The ELS SM will already be receiving ELS_REQ_OK/FAIL/RJT/ABORTED
*/
ocs_els_post_event(els, OCS_EVT_ELS_ABORT_CMPL, NULL);
/* done with ELS IO to abort */
ocs_ref_put(&els->ref); /* ocs_ref_get(): ocs_els_abort_io() */
return 0;
}
/**
* @brief Abort an ELS IO.
*
* <h3 class="desc">Description</h3>
* The ELS IO is aborted by making a HW abort IO request,
* optionally requesting that an ABTS is sent.
*
* \b Note: This function allocates a HW IO, and associates the HW IO
* with the ELS IO that it is aborting. It does not associate
* the HW IO with the node directly, like for ELS requests. The
* abort completion is propagated up to the node once the
* original WQE and the abort WQE are complete (the original WQE
* completion is not propagated up to node).
*
* @param els Pointer to the ELS IO.
* @param send_abts Boolean to indicate if hardware will automatically generate an ABTS.
*
* @return Returns pointer to Abort IO object, or NULL if error.
*/
static ocs_io_t *
ocs_els_abort_io(ocs_io_t *els, int send_abts)
{
ocs_t *ocs;
ocs_xport_t *xport;
int32_t rc;
ocs_io_t *abort_io = NULL;
ocs_assert(els, NULL);
ocs_assert(els->node, NULL);
ocs_assert(els->node->ocs, NULL);
ocs = els->node->ocs;
ocs_assert(ocs->xport, NULL);
xport = ocs->xport;
/* take a reference on IO being aborted */
if ((ocs_ref_get_unless_zero(&els->ref) == 0)) {
/* command no longer active */
ocs_log_debug(ocs, "els no longer active\n");
return NULL;
}
/* allocate IO structure to send abort */
abort_io = ocs_io_alloc(ocs);
if (abort_io == NULL) {
ocs_atomic_add_return(&xport->io_alloc_failed_count, 1);
} else {
ocs_assert(abort_io->hio == NULL, NULL);
/* set generic fields */
abort_io->ocs = ocs;
abort_io->node = els->node;
abort_io->cmd_ini = TRUE;
/* set type and ABORT-specific fields */
abort_io->io_type = OCS_IO_TYPE_ABORT;
abort_io->display_name = "abort_els";
abort_io->io_to_abort = els;
abort_io->send_abts = send_abts;
/* now dispatch IO */
if ((rc = ocs_scsi_io_dispatch_abort(abort_io, ocs_els_abort_cb))) {
ocs_log_err(ocs, "ocs_scsi_io_dispatch failed: %d\n", rc);
ocs_io_free(ocs, abort_io);
abort_io = NULL;
}
}
/* if something failed, put reference on ELS to abort */
if (abort_io == NULL) {
ocs_ref_put(&els->ref); /* ocs_ref_get(): same function */
}
return abort_io;
}
/*
* ELS IO State Machine
*/
#define std_els_state_decl(...) \
ocs_io_t *els = NULL; \
ocs_node_t *node = NULL; \
ocs_t *ocs = NULL; \
ocs_assert(ctx != NULL, NULL); \
els = ctx->app; \
ocs_assert(els != NULL, NULL); \
node = els->node; \
ocs_assert(node != NULL, NULL); \
ocs = node->ocs; \
ocs_assert(ocs != NULL, NULL);
#define els_sm_trace(...) \
do { \
if (OCS_LOG_ENABLE_ELS_TRACE(ocs)) \
ocs_log_info(ocs, "[%s] %-8s %-20s %-20s\n", node->display_name, els->display_name, \
__func__, ocs_sm_event_name(evt)); \
} while (0)
/**
* @brief Cleanup an ELS IO
*
* <h3 class="desc">Description</h3>
* Cleans up an ELS IO by posting the requested event to the owning node object;
* invoking the callback, if one is provided; and then freeing the
* ELS IO object.
*
* @param els Pointer to the ELS IO.
* @param node_evt Node SM event to post.
* @param arg Node SM event argument.
*
* @return None.
*/
void
ocs_els_io_cleanup(ocs_io_t *els, ocs_sm_event_t node_evt, void *arg)
{
ocs_assert(els);
/* don't want further events that could come; e.g. abort requests
* from the node state machine; thus, disable state machine
*/
ocs_sm_disable(&els->els_sm);
ocs_node_post_event(els->node, node_evt, arg);
/* If this IO has a callback, invoke it */
if (els->els_callback) {
(*els->els_callback)(els->node, arg, els->els_callback_arg);
}
els->els_req_free = 1;
}
/**
* @brief Common event handler for the ELS IO state machine.
*
* <h3 class="desc">Description</h3>
* Provide handler for events for which default actions are desired.
*
* @param funcname Name of the calling function (for logging).
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_common(const char *funcname, ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
switch(evt) {
case OCS_EVT_ENTER:
case OCS_EVT_REENTER:
case OCS_EVT_EXIT:
break;
/* If ELS_REQ_FAIL is not handled in state, then we'll terminate this ELS and
* pass the event to the node
*/
case OCS_EVT_SRRS_ELS_REQ_FAIL:
ocs_log_warn(els->node->ocs, "[%s] %-20s %-20s not handled - terminating ELS\n", node->display_name, funcname,
ocs_sm_event_name(evt));
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, arg);
break;
default:
ocs_log_warn(els->node->ocs, "[%s] %-20s %-20s not handled\n", node->display_name, funcname,
ocs_sm_event_name(evt));
break;
}
return NULL;
}
/**
* @brief Initial ELS IO state
*
* <h3 class="desc">Description</h3>
* This is the initial ELS IO state. Upon entry, the requested ELS/CT is submitted to
* the hardware.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_init(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
int32_t rc = 0;
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_ENTER: {
rc = ocs_els_send(els, els->els_req.size, els->els_timeout_sec, ocs_els_req_cb);
if (rc) {
ocs_node_cb_t cbdata;
cbdata.status = cbdata.ext_status = (~0);
cbdata.els = els;
ocs_log_err(ocs, "ocs_els_send failed: %d\n", rc);
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &cbdata);
} else {
ocs_io_transition(els, __ocs_els_wait_resp, NULL);
}
break;
}
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for the ELS request to complete.
*
* <h3 class="desc">Description</h3>
* This is the ELS IO state that waits for the submitted ELS event to complete.
* If an error completion event is received, the requested ELS is aborted.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_wait_resp(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
ocs_io_t *io;
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_SRRS_ELS_REQ_OK: {
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_OK, arg);
break;
}
case OCS_EVT_SRRS_ELS_REQ_FAIL: {
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, arg);
break;
}
case OCS_EVT_ELS_REQ_TIMEOUT: {
els_io_printf(els, "Timed out, retry (%d tries remaining)\n",
els->els_retries_remaining-1);
ocs_io_transition(els, __ocs_els_retry, NULL);
break;
}
case OCS_EVT_SRRS_ELS_REQ_RJT: {
ocs_node_cb_t *cbdata = arg;
uint32_t reason_code = (cbdata->ext_status >> 16) & 0xff;
/* delay and retry if reason code is Logical Busy */
switch (reason_code) {
case FC_REASON_LOGICAL_BUSY:
els->node->els_req_cnt--;
els_io_printf(els, "LS_RJT Logical Busy response, delay and retry\n");
ocs_io_transition(els, __ocs_els_delay_retry, NULL);
break;
default:
ocs_els_io_cleanup(els, evt, arg);
break;
}
break;
}
case OCS_EVT_ABORT_ELS: {
/* request to abort this ELS without an ABTS */
els_io_printf(els, "ELS abort requested\n");
els->els_retries_remaining = 0; /* Set retries to zero, we are done */
io = ocs_els_abort_io(els, FALSE);
if (io == NULL) {
ocs_log_err(ocs, "ocs_els_send failed\n");
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, arg);
} else {
ocs_io_transition(els, __ocs_els_aborting, NULL);
}
break;
}
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for the ELS IO abort request to complete, and retry the ELS.
*
* <h3 class="desc">Description</h3>
* This state is entered when waiting for an abort of an ELS
* request to complete so the request can be retried.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_retry(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
int32_t rc = 0;
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_ENTER: {
/* handle event for ABORT_XRI WQE
* once abort is complete, retry if retries left;
* don't need to wait for OCS_EVT_SRRS_ELS_REQ_* event because we got
* by receiving OCS_EVT_ELS_REQ_TIMEOUT
*/
ocs_node_cb_t node_cbdata;
node_cbdata.status = node_cbdata.ext_status = (~0);
node_cbdata.els = els;
if (els->els_retries_remaining && --els->els_retries_remaining) {
/* Use a different XRI for the retry (would like a new oxid),
* so free the HW IO (dispatch will allocate a new one). It's an
* optimization to only free the HW IO here and not the ocs_io_t;
* Freeing the ocs_io_t object would require copying all the necessary
* info from the old ocs_io_t object to the * new one; and allocating
* a new ocs_io_t could fail.
*/
ocs_assert(els->hio, NULL);
ocs_hw_io_free(&ocs->hw, els->hio);
els->hio = NULL;
/* result isn't propagated up to node sm, need to decrement req cnt */
ocs_assert(els->node->els_req_cnt, NULL);
els->node->els_req_cnt--;
rc = ocs_els_send(els, els->els_req.size, els->els_timeout_sec, ocs_els_req_cb);
if (rc) {
ocs_log_err(ocs, "ocs_els_send failed: %d\n", rc);
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &node_cbdata);
}
ocs_io_transition(els, __ocs_els_wait_resp, NULL);
} else {
els_io_printf(els, "Retries exhausted\n");
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, &node_cbdata);
}
break;
}
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for a retry timer to expire having received an abort request
*
* <h3 class="desc">Description</h3>
* This state is entered when waiting for a timer event, after having received
* an abort request, to avoid a race condition with the timer handler
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_aborted_delay_retry(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_ENTER:
/* mod/resched the timer for a short duration */
ocs_mod_timer(&els->delay_timer, 1);
break;
case OCS_EVT_TIMER_EXPIRED:
/* Cancel the timer, skip post node event, and free the io */
node->els_req_cnt++;
ocs_els_io_cleanup(els, OCS_EVT_SRRS_ELS_REQ_FAIL, arg);
break;
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for a retry timer to expire
*
* <h3 class="desc">Description</h3>
* This state is entered when waiting for a timer event, so that
* the ELS request can be retried.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_delay_retry(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_ENTER:
ocs_setup_timer(ocs, &els->delay_timer, ocs_els_delay_timer_cb, els, 5000);
break;
case OCS_EVT_TIMER_EXPIRED:
/* Retry delay timer expired, retry the ELS request, Free the HW IO so
* that a new oxid is used.
*/
if (els->hio != NULL) {
ocs_hw_io_free(&ocs->hw, els->hio);
els->hio = NULL;
}
ocs_io_transition(els, __ocs_els_init, NULL);
break;
case OCS_EVT_ABORT_ELS:
ocs_io_transition(els, __ocs_els_aborted_delay_retry, NULL);
break;
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for the ELS IO abort request to complete.
*
* <h3 class="desc">Description</h3>
* This state is entered after we abort an ELS WQE and are
* waiting for either the original ELS WQE request or the abort
* to complete.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_aborting(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_SRRS_ELS_REQ_OK:
case OCS_EVT_SRRS_ELS_REQ_FAIL:
case OCS_EVT_SRRS_ELS_REQ_RJT:
case OCS_EVT_ELS_REQ_TIMEOUT:
case OCS_EVT_ELS_REQ_ABORTED: {
/* completion for ELS received first, transition to wait for abort cmpl */
els_io_printf(els, "request cmpl evt=%s\n", ocs_sm_event_name(evt));
ocs_io_transition(els, __ocs_els_aborting_wait_abort_cmpl, NULL);
break;
}
case OCS_EVT_ELS_ABORT_CMPL: {
/* completion for abort was received first, transition to wait for req cmpl */
els_io_printf(els, "abort cmpl evt=%s\n", ocs_sm_event_name(evt));
ocs_io_transition(els, __ocs_els_aborting_wait_req_cmpl, NULL);
break;
}
case OCS_EVT_ABORT_ELS:
/* nothing we can do but wait */
break;
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief cleanup ELS after abort
*
* @param els ELS IO to cleanup
*
* @return Returns None.
*/
static void
ocs_els_abort_cleanup(ocs_io_t *els)
{
/* handle event for ABORT_WQE
* whatever state ELS happened to be in, propagate aborted event up
* to node state machine in lieu of OCS_EVT_SRRS_ELS_* event
*/
ocs_node_cb_t cbdata;
cbdata.status = cbdata.ext_status = 0;
cbdata.els = els;
els_io_printf(els, "Request aborted\n");
ocs_els_io_cleanup(els, OCS_EVT_ELS_REQ_ABORTED, &cbdata);
}
/**
* @brief Wait for the ELS IO abort request to complete.
*
* <h3 class="desc">Description</h3>
* This state is entered after we abort an ELS WQE, we received
* the abort completion first and are waiting for the original
* ELS WQE request to complete.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_aborting_wait_req_cmpl(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_SRRS_ELS_REQ_OK:
case OCS_EVT_SRRS_ELS_REQ_FAIL:
case OCS_EVT_SRRS_ELS_REQ_RJT:
case OCS_EVT_ELS_REQ_TIMEOUT:
case OCS_EVT_ELS_REQ_ABORTED: {
/* completion for ELS that was aborted */
ocs_els_abort_cleanup(els);
break;
}
case OCS_EVT_ABORT_ELS:
/* nothing we can do but wait */
break;
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Wait for the ELS IO abort request to complete.
*
* <h3 class="desc">Description</h3>
* This state is entered after we abort an ELS WQE, we received
* the original ELS WQE request completion first and are waiting
* for the abort to complete.
*
* @param ctx Remote node SM context.
* @param evt Event to process.
* @param arg Per event optional argument.
*
* @return Returns NULL.
*/
void *
__ocs_els_aborting_wait_abort_cmpl(ocs_sm_ctx_t *ctx, ocs_sm_event_t evt, void *arg)
{
std_els_state_decl();
els_sm_trace();
switch(evt) {
case OCS_EVT_ELS_ABORT_CMPL: {
ocs_els_abort_cleanup(els);
break;
}
case OCS_EVT_ABORT_ELS:
/* nothing we can do but wait */
break;
default:
__ocs_els_common(__func__, ctx, evt, arg);
break;
}
return NULL;
}
/**
* @brief Generate ELS context ddump data.
*
* <h3 class="desc">Description</h3>
* Generate the ddump data for an ELS context.
*
* @param textbuf Pointer to the text buffer.
* @param els Pointer to the ELS context.
*
* @return None.
*/
void
ocs_ddump_els(ocs_textbuf_t *textbuf, ocs_io_t *els)
{
ocs_ddump_section(textbuf, "els", -1);
ocs_ddump_value(textbuf, "req_free", "%d", els->els_req_free);
ocs_ddump_value(textbuf, "evtdepth", "%d", els->els_evtdepth);
ocs_ddump_value(textbuf, "pend", "%d", els->els_pend);
ocs_ddump_value(textbuf, "active", "%d", els->els_active);
ocs_ddump_io(textbuf, els);
ocs_ddump_endsection(textbuf, "els", -1);
}
/**
* @brief return TRUE if given ELS list is empty (while taking proper locks)
*
* Test if given ELS list is empty while holding the node->active_ios_lock.
*
* @param node pointer to node object
* @param list pointer to list
*
* @return TRUE if els_io_list is empty
*/
int32_t
ocs_els_io_list_empty(ocs_node_t *node, ocs_list_t *list)
{
int empty;
ocs_lock(&node->active_ios_lock);
empty = ocs_list_empty(list);
ocs_unlock(&node->active_ios_lock);
return empty;
}
/**
* @brief Handle CT send response completion
*
* Called when CT response completes, free IO
*
* @param hio Pointer to the HW IO context that completed.
* @param rnode Pointer to the remote node.
* @param length Length of the returned payload data.
* @param status Status of the completion.
* @param ext_status Extended status of the completion.
* @param arg Application-specific argument (generally a pointer to the ELS IO context).
*
* @return returns 0
*/
static int32_t
ocs_ct_acc_cb(ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t length, int32_t status, uint32_t ext_status, void *arg)
{
ocs_io_t *io = arg;
ocs_els_io_free(io);
return 0;
}
/**
* @brief Send CT response
*
* Sends a CT response frame with payload
*
* @param io Pointer to the IO context.
* @param ox_id Originator exchange ID
* @param ct_hdr Pointer to the CT IU
* @param cmd_rsp_code CT response code
* @param reason_code Reason code
* @param reason_code_explanation Reason code explanation
*
* @return returns 0 for success, a negative error code value for failure.
*/
int32_t
ocs_send_ct_rsp(ocs_io_t *io, uint32_t ox_id, fcct_iu_header_t *ct_hdr, uint32_t cmd_rsp_code, uint32_t reason_code, uint32_t reason_code_explanation)
{
fcct_iu_header_t *rsp = io->els_rsp.virt;
io->io_type = OCS_IO_TYPE_CT_RESP;
*rsp = *ct_hdr;
fcct_build_req_header(rsp, cmd_rsp_code, 0);
rsp->reason_code = reason_code;
rsp->reason_code_explanation = reason_code_explanation;
io->display_name = "ct response";
io->init_task_tag = ox_id;
io->wire_len += sizeof(*rsp);
ocs_memset(&io->iparam, 0, sizeof(io->iparam));
io->io_type = OCS_IO_TYPE_CT_RESP;
io->hio_type = OCS_HW_FC_CT_RSP;
io->iparam.fc_ct_rsp.ox_id = ocs_htobe16(ox_id);
io->iparam.fc_ct_rsp.r_ctl = 3;
io->iparam.fc_ct_rsp.type = FC_TYPE_GS;
io->iparam.fc_ct_rsp.df_ctl = 0;
io->iparam.fc_ct_rsp.timeout = 5;
if (ocs_scsi_io_dispatch(io, ocs_ct_acc_cb) < 0) {
ocs_els_io_free(io);
return -1;
}
return 0;
}
/**
* @brief Handle delay retry timeout
*
* Callback is invoked when the delay retry timer expires.
*
* @param arg pointer to the ELS IO object
*
* @return none
*/
static void
ocs_els_delay_timer_cb(void *arg)
{
ocs_io_t *els = arg;
ocs_node_t *node = els->node;
/*
* There is a potential deadlock here since is Linux executes timers
* in a soft IRQ context. The lock may be aready locked by the interrupt
* thread. Handle this case by attempting to take the node lock and reset the
* timer if we fail to acquire the lock.
*
* Note: This code relies on the fact that the node lock is recursive.
*/
if (ocs_node_lock_try(node)) {
ocs_els_post_event(els, OCS_EVT_TIMER_EXPIRED, NULL);
ocs_node_unlock(node);
} else {
ocs_setup_timer(els->ocs, &els->delay_timer, ocs_els_delay_timer_cb, els, 1);
}
}