freebsd-nq/sys/dev/ocs_fc/ocs_unsol.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

1400 lines
39 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
* Code to handle unsolicited received FC frames.
*/
/*!
* @defgroup unsol Unsolicited Frame Handling
*/
#include "ocs.h"
#include "ocs_els.h"
#include "ocs_fabric.h"
#include "ocs_device.h"
#define frame_printf(ocs, hdr, fmt, ...) \
do { \
char s_id_text[16]; \
ocs_node_fcid_display(fc_be24toh((hdr)->s_id), s_id_text, sizeof(s_id_text)); \
ocs_log_debug(ocs, "[%06x.%s] %02x/%04x/%04x: " fmt, fc_be24toh((hdr)->d_id), s_id_text, \
(hdr)->r_ctl, ocs_be16toh((hdr)->ox_id), ocs_be16toh((hdr)->rx_id), ##__VA_ARGS__); \
} while(0)
static int32_t ocs_unsol_process(ocs_t *ocs, ocs_hw_sequence_t *seq);
static int32_t ocs_dispatch_fcp_cmd(ocs_node_t *node, ocs_hw_sequence_t *seq);
static int32_t ocs_dispatch_fcp_cmd_auto_xfer_rdy(ocs_node_t *node, ocs_hw_sequence_t *seq);
static int32_t ocs_dispatch_fcp_data(ocs_node_t *node, ocs_hw_sequence_t *seq);
static int32_t ocs_domain_dispatch_frame(void *arg, ocs_hw_sequence_t *seq);
static int32_t ocs_node_dispatch_frame(void *arg, ocs_hw_sequence_t *seq);
static int32_t ocs_fc_tmf_rejected_cb(ocs_io_t *io, ocs_scsi_io_status_e scsi_status, uint32_t flags, void *arg);
static ocs_hw_sequence_t *ocs_frame_next(ocs_list_t *pend_list, ocs_lock_t *list_lock);
static uint8_t ocs_node_frames_held(void *arg);
static uint8_t ocs_domain_frames_held(void *arg);
static int32_t ocs_purge_pending(ocs_t *ocs, ocs_list_t *pend_list, ocs_lock_t *list_lock);
static int32_t ocs_sframe_send_task_set_full_or_busy(ocs_node_t *node, ocs_hw_sequence_t *seq);
#define OCS_MAX_FRAMES_BEFORE_YEILDING 10000
/**
* @brief Process the RQ circular buffer and process the incoming frames.
*
* @param mythread Pointer to thread object.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
ocs_unsol_rq_thread(ocs_thread_t *mythread)
{
ocs_xport_rq_thread_info_t *thread_data = mythread->arg;
ocs_t *ocs = thread_data->ocs;
ocs_hw_sequence_t *seq;
uint32_t yield_count = OCS_MAX_FRAMES_BEFORE_YEILDING;
ocs_log_debug(ocs, "%s running\n", mythread->name);
while (!ocs_thread_terminate_requested(mythread)) {
seq = ocs_cbuf_get(thread_data->seq_cbuf, 100000);
if (seq == NULL) {
/* Prevent soft lockups by yielding the CPU */
ocs_thread_yield(&thread_data->thread);
yield_count = OCS_MAX_FRAMES_BEFORE_YEILDING;
continue;
}
/* Note: Always returns 0 */
ocs_unsol_process((ocs_t*)seq->hw->os, seq);
/* We have to prevent CPU soft lockups, so just yield the CPU after x frames. */
if (--yield_count == 0) {
ocs_thread_yield(&thread_data->thread);
yield_count = OCS_MAX_FRAMES_BEFORE_YEILDING;
}
}
ocs_log_debug(ocs, "%s exiting\n", mythread->name);
thread_data->thread_started = FALSE;
return 0;
}
/**
* @ingroup unsol
* @brief Callback function when aborting a port owned XRI
* exchanges.
*
* @return Returns 0.
*/
static int32_t
ocs_unsol_abort_cb (ocs_hw_io_t *hio, ocs_remote_node_t *rnode, uint32_t len, int32_t status, uint32_t ext, void *arg)
{
ocs_t *ocs = arg;
ocs_assert(hio, -1);
ocs_assert(arg, -1);
ocs_log_debug(ocs, "xri=0x%x tag=0x%x\n", hio->indicator, hio->reqtag);
ocs_hw_io_free(&ocs->hw, hio);
return 0;
}
/**
* @ingroup unsol
* @brief Abort either a RQ Pair auto XFER RDY XRI.
* @return Returns None.
*/
static void
ocs_port_owned_abort(ocs_t *ocs, ocs_hw_io_t *hio)
{
ocs_hw_rtn_e hw_rc;
hw_rc = ocs_hw_io_abort(&ocs->hw, hio, FALSE,
ocs_unsol_abort_cb, ocs);
if((hw_rc == OCS_HW_RTN_IO_ABORT_IN_PROGRESS) ||
(hw_rc == OCS_HW_RTN_IO_PORT_OWNED_ALREADY_ABORTED)) {
ocs_log_debug(ocs, "already aborted XRI 0x%x\n", hio->indicator);
} else if(hw_rc != OCS_HW_RTN_SUCCESS) {
ocs_log_debug(ocs, "Error aborting XRI 0x%x status %d\n",
hio->indicator, hw_rc);
}
}
/**
* @ingroup unsol
* @brief Handle unsolicited FC frames.
*
* <h3 class="desc">Description</h3>
* This function is called from the HW with unsolicited FC frames (FCP, ELS, BLS, etc.).
*
* @param arg Application-specified callback data.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 on success; or a negative error value on failure.
*/
int32_t
ocs_unsolicited_cb(void *arg, ocs_hw_sequence_t *seq)
{
ocs_t *ocs = arg;
ocs_xport_t *xport = ocs->xport;
int32_t rc;
CPUTRACE("");
if (ocs->rq_threads == 0) {
rc = ocs_unsol_process(ocs, seq);
} else {
/* use the ox_id to dispatch this IO to a thread */
fc_header_t *hdr = seq->header->dma.virt;
uint32_t ox_id = ocs_be16toh(hdr->ox_id);
uint32_t thr_index = ox_id % ocs->rq_threads;
rc = ocs_cbuf_put(xport->rq_thread_info[thr_index].seq_cbuf, seq);
}
if (rc) {
ocs_hw_sequence_free(&ocs->hw, seq);
}
return 0;
}
/**
* @ingroup unsol
* @brief Handle unsolicited FC frames.
*
* <h3 class="desc">Description</h3>
* This function is called either from ocs_unsolicited_cb() or ocs_unsol_rq_thread().
*
* @param ocs Pointer to the ocs structure.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
static int32_t
ocs_unsol_process(ocs_t *ocs, ocs_hw_sequence_t *seq)
{
ocs_xport_fcfi_t *xport_fcfi = NULL;
ocs_domain_t *domain;
uint8_t seq_fcfi = seq->fcfi;
/* HW_WORKAROUND_OVERRIDE_FCFI_IN_SRB */
if (ocs->hw.workaround.override_fcfi) {
if (ocs->hw.first_domain_idx > -1) {
seq_fcfi = ocs->hw.first_domain_idx;
}
}
/* Range check seq->fcfi */
if (seq_fcfi < ARRAY_SIZE(ocs->xport->fcfi)) {
xport_fcfi = &ocs->xport->fcfi[seq_fcfi];
}
/* If the transport FCFI entry is NULL, then drop the frame */
if (xport_fcfi == NULL) {
ocs_log_test(ocs, "FCFI %d is not valid, dropping frame\n", seq->fcfi);
if (seq->hio != NULL) {
ocs_port_owned_abort(ocs, seq->hio);
}
ocs_hw_sequence_free(&ocs->hw, seq);
return 0;
}
domain = ocs_hw_domain_get(&ocs->hw, seq_fcfi);
/*
* If we are holding frames or the domain is not yet registered or
* there's already frames on the pending list,
* then add the new frame to pending list
*/
if (domain == NULL ||
xport_fcfi->hold_frames ||
!ocs_list_empty(&xport_fcfi->pend_frames)) {
ocs_lock(&xport_fcfi->pend_frames_lock);
ocs_list_add_tail(&xport_fcfi->pend_frames, seq);
ocs_unlock(&xport_fcfi->pend_frames_lock);
if (domain != NULL) {
/* immediately process pending frames */
ocs_domain_process_pending(domain);
}
} else {
/*
* We are not holding frames and pending list is empty, just process frame.
* A non-zero return means the frame was not handled - so cleanup
*/
if (ocs_domain_dispatch_frame(domain, seq)) {
if (seq->hio != NULL) {
ocs_port_owned_abort(ocs, seq->hio);
}
ocs_hw_sequence_free(&ocs->hw, seq);
}
}
return 0;
}
/**
* @ingroup unsol
* @brief Process pending frames queued to the given node.
*
* <h3 class="desc">Description</h3>
* Frames that are queued for the \c node are dispatched and returned
* to the RQ.
*
* @param node Node of the queued frames that are to be dispatched.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
int32_t
ocs_process_node_pending(ocs_node_t *node)
{
ocs_t *ocs = node->ocs;
ocs_hw_sequence_t *seq = NULL;
uint32_t pend_frames_processed = 0;
for (;;) {
/* need to check for hold frames condition after each frame processed
* because any given frame could cause a transition to a state that
* holds frames
*/
if (ocs_node_frames_held(node)) {
break;
}
/* Get next frame/sequence */
ocs_lock(&node->pend_frames_lock);
seq = ocs_list_remove_head(&node->pend_frames);
if (seq == NULL) {
pend_frames_processed = node->pend_frames_processed;
node->pend_frames_processed = 0;
ocs_unlock(&node->pend_frames_lock);
break;
}
node->pend_frames_processed++;
ocs_unlock(&node->pend_frames_lock);
/* now dispatch frame(s) to dispatch function */
if (ocs_node_dispatch_frame(node, seq)) {
if (seq->hio != NULL) {
ocs_port_owned_abort(ocs, seq->hio);
}
ocs_hw_sequence_free(&ocs->hw, seq);
}
}
if (pend_frames_processed != 0) {
ocs_log_debug(ocs, "%u node frames held and processed\n", pend_frames_processed);
}
return 0;
}
/**
* @ingroup unsol
* @brief Process pending frames queued to the given domain.
*
* <h3 class="desc">Description</h3>
* Frames that are queued for the \c domain are dispatched and
* returned to the RQ.
*
* @param domain Domain of the queued frames that are to be
* dispatched.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
int32_t
ocs_domain_process_pending(ocs_domain_t *domain)
{
ocs_t *ocs = domain->ocs;
ocs_xport_fcfi_t *xport_fcfi;
ocs_hw_sequence_t *seq = NULL;
uint32_t pend_frames_processed = 0;
ocs_assert(domain->fcf_indicator < SLI4_MAX_FCFI, -1);
xport_fcfi = &ocs->xport->fcfi[domain->fcf_indicator];
for (;;) {
/* need to check for hold frames condition after each frame processed
* because any given frame could cause a transition to a state that
* holds frames
*/
if (ocs_domain_frames_held(domain)) {
break;
}
/* Get next frame/sequence */
ocs_lock(&xport_fcfi->pend_frames_lock);
seq = ocs_list_remove_head(&xport_fcfi->pend_frames);
if (seq == NULL) {
pend_frames_processed = xport_fcfi->pend_frames_processed;
xport_fcfi->pend_frames_processed = 0;
ocs_unlock(&xport_fcfi->pend_frames_lock);
break;
}
xport_fcfi->pend_frames_processed++;
ocs_unlock(&xport_fcfi->pend_frames_lock);
/* now dispatch frame(s) to dispatch function */
if (ocs_domain_dispatch_frame(domain, seq)) {
if (seq->hio != NULL) {
ocs_port_owned_abort(ocs, seq->hio);
}
ocs_hw_sequence_free(&ocs->hw, seq);
}
}
if (pend_frames_processed != 0) {
ocs_log_debug(ocs, "%u domain frames held and processed\n", pend_frames_processed);
}
return 0;
}
/**
* @ingroup unsol
* @brief Purge given pending list
*
* <h3 class="desc">Description</h3>
* Frames that are queued on the given pending list are
* discarded and returned to the RQ.
*
* @param ocs Pointer to ocs object.
* @param pend_list Pending list to be purged.
* @param list_lock Lock that protects pending list.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
static int32_t
ocs_purge_pending(ocs_t *ocs, ocs_list_t *pend_list, ocs_lock_t *list_lock)
{
ocs_hw_sequence_t *frame;
for (;;) {
frame = ocs_frame_next(pend_list, list_lock);
if (frame == NULL) {
break;
}
frame_printf(ocs, (fc_header_t*) frame->header->dma.virt, "Discarding held frame\n");
if (frame->hio != NULL) {
ocs_port_owned_abort(ocs, frame->hio);
}
ocs_hw_sequence_free(&ocs->hw, frame);
}
return 0;
}
/**
* @ingroup unsol
* @brief Purge node's pending (queued) frames.
*
* <h3 class="desc">Description</h3>
* Frames that are queued for the \c node are discarded and returned
* to the RQ.
*
* @param node Node of the queued frames that are to be discarded.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
int32_t
ocs_node_purge_pending(ocs_node_t *node)
{
return ocs_purge_pending(node->ocs, &node->pend_frames, &node->pend_frames_lock);
}
/**
* @ingroup unsol
* @brief Purge xport's pending (queued) frames.
*
* <h3 class="desc">Description</h3>
* Frames that are queued for the \c xport are discarded and
* returned to the RQ.
*
* @param domain Pointer to domain object.
*
* @return Returns 0 on success; or a negative error value on failure.
*/
int32_t
ocs_domain_purge_pending(ocs_domain_t *domain)
{
ocs_t *ocs = domain->ocs;
ocs_xport_fcfi_t *xport_fcfi;
ocs_assert(domain->fcf_indicator < SLI4_MAX_FCFI, -1);
xport_fcfi = &ocs->xport->fcfi[domain->fcf_indicator];
return ocs_purge_pending(domain->ocs,
&xport_fcfi->pend_frames,
&xport_fcfi->pend_frames_lock);
}
/**
* @ingroup unsol
* @brief Check if node's pending frames are held.
*
* @param arg Node for which the pending frame hold condition is
* checked.
*
* @return Returns 1 if node is holding pending frames, or 0
* if not.
*/
static uint8_t
ocs_node_frames_held(void *arg)
{
ocs_node_t *node = (ocs_node_t *)arg;
return node->hold_frames;
}
/**
* @ingroup unsol
* @brief Check if domain's pending frames are held.
*
* @param arg Domain for which the pending frame hold condition is
* checked.
*
* @return Returns 1 if domain is holding pending frames, or 0
* if not.
*/
static uint8_t
ocs_domain_frames_held(void *arg)
{
ocs_domain_t *domain = (ocs_domain_t *)arg;
ocs_t *ocs = domain->ocs;
ocs_xport_fcfi_t *xport_fcfi;
ocs_assert(domain != NULL, 1);
ocs_assert(domain->fcf_indicator < SLI4_MAX_FCFI, 1);
xport_fcfi = &ocs->xport->fcfi[domain->fcf_indicator];
return xport_fcfi->hold_frames;
}
/**
* @ingroup unsol
* @brief Globally (at xport level) hold unsolicited frames.
*
* <h3 class="desc">Description</h3>
* This function places a hold on processing unsolicited FC
* frames queued to the xport pending list.
*
* @param domain Pointer to domain object.
*
* @return Returns None.
*/
void
ocs_domain_hold_frames(ocs_domain_t *domain)
{
ocs_t *ocs = domain->ocs;
ocs_xport_fcfi_t *xport_fcfi;
ocs_assert(domain->fcf_indicator < SLI4_MAX_FCFI);
xport_fcfi = &ocs->xport->fcfi[domain->fcf_indicator];
if (!xport_fcfi->hold_frames) {
ocs_log_debug(domain->ocs, "hold frames set for FCFI %d\n",
domain->fcf_indicator);
xport_fcfi->hold_frames = 1;
}
}
/**
* @ingroup unsol
* @brief Clear hold on unsolicited frames.
*
* <h3 class="desc">Description</h3>
* This function clears the hold on processing unsolicited FC
* frames queued to the domain pending list.
*
* @param domain Pointer to domain object.
*
* @return Returns None.
*/
void
ocs_domain_accept_frames(ocs_domain_t *domain)
{
ocs_t *ocs = domain->ocs;
ocs_xport_fcfi_t *xport_fcfi;
ocs_assert(domain->fcf_indicator < SLI4_MAX_FCFI);
xport_fcfi = &ocs->xport->fcfi[domain->fcf_indicator];
if (xport_fcfi->hold_frames == 1) {
ocs_log_debug(domain->ocs, "hold frames cleared for FCFI %d\n",
domain->fcf_indicator);
}
xport_fcfi->hold_frames = 0;
ocs_domain_process_pending(domain);
}
/**
* @ingroup unsol
* @brief Dispatch unsolicited FC frame.
*
* <h3 class="desc">Description</h3>
* This function processes an unsolicited FC frame queued at the
* domain level.
*
* @param arg Pointer to ocs object.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 if frame processed and RX buffers cleaned
* up appropriately, -1 if frame not handled.
*/
static __inline int32_t
ocs_domain_dispatch_frame(void *arg, ocs_hw_sequence_t *seq)
{
ocs_domain_t *domain = (ocs_domain_t *)arg;
ocs_t *ocs = domain->ocs;
fc_header_t *hdr;
uint32_t s_id;
uint32_t d_id;
ocs_node_t *node = NULL;
ocs_sport_t *sport = NULL;
ocs_assert(seq->header, -1);
ocs_assert(seq->header->dma.virt, -1);
ocs_assert(seq->payload->dma.virt, -1);
hdr = seq->header->dma.virt;
/* extract the s_id and d_id */
s_id = fc_be24toh(hdr->s_id);
d_id = fc_be24toh(hdr->d_id);
sport = domain->sport;
if (sport == NULL) {
frame_printf(ocs, hdr, "phy sport for FC ID 0x%06x is NULL, dropping frame\n", d_id);
return -1;
}
if (sport->fc_id != d_id) {
/* Not a physical port IO lookup sport associated with the npiv port */
sport = ocs_sport_find(domain, d_id); /* Look up without lock */
if (sport == NULL) {
if (hdr->type == FC_TYPE_FCP) {
/* Drop frame */
ocs_log_warn(ocs, "unsolicited FCP frame with invalid d_id x%x, dropping\n",
d_id);
return -1;
} else {
/* p2p will use this case */
sport = domain->sport;
}
}
}
/* Lookup the node given the remote s_id */
node = ocs_node_find(sport, s_id);
/* If not found, then create a new node */
if (node == NULL) {
/* If this is solicited data or control based on R_CTL and there is no node context,
* then we can drop the frame
*/
if ((hdr->r_ctl == FC_RCTL_FC4_DATA) && (
(hdr->info == FC_RCTL_INFO_SOL_DATA) || (hdr->info == FC_RCTL_INFO_SOL_CTRL))) {
ocs_log_debug(ocs, "solicited data/ctrl frame without node, dropping\n");
return -1;
}
node = ocs_node_alloc(sport, s_id, FALSE, FALSE);
if (node == NULL) {
ocs_log_err(ocs, "ocs_node_alloc() failed\n");
return -1;
}
/* don't send PLOGI on ocs_d_init entry */
ocs_node_init_device(node, FALSE);
}
if (node->hold_frames || !ocs_list_empty((&node->pend_frames))) {
/* TODO: info log level
frame_printf(ocs, hdr, "Holding frame\n");
*/
/* add frame to node's pending list */
ocs_lock(&node->pend_frames_lock);
ocs_list_add_tail(&node->pend_frames, seq);
ocs_unlock(&node->pend_frames_lock);
return 0;
}
/* now dispatch frame to the node frame handler */
return ocs_node_dispatch_frame(node, seq);
}
/**
* @ingroup unsol
* @brief Dispatch a frame.
*
* <h3 class="desc">Description</h3>
* A frame is dispatched from the \c node to the handler.
*
* @param arg Node that originated the frame.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 if frame processed and RX buffers cleaned
* up appropriately, -1 if frame not handled.
*/
static int32_t
ocs_node_dispatch_frame(void *arg, ocs_hw_sequence_t *seq)
{
fc_header_t *hdr = seq->header->dma.virt;
uint32_t port_id;
ocs_node_t *node = (ocs_node_t *)arg;
int32_t rc = -1;
int32_t sit_set = 0;
port_id = fc_be24toh(hdr->s_id);
ocs_assert(port_id == node->rnode.fc_id, -1);
if (fc_be24toh(hdr->f_ctl) & FC_FCTL_END_SEQUENCE) {
/*if SIT is set */
if (fc_be24toh(hdr->f_ctl) & FC_FCTL_SEQUENCE_INITIATIVE) {
sit_set = 1;
}
switch (hdr->r_ctl) {
case FC_RCTL_ELS:
if (sit_set) {
rc = ocs_node_recv_els_frame(node, seq);
}
break;
case FC_RCTL_BLS:
if (sit_set) {
rc = ocs_node_recv_abts_frame(node, seq);
}else {
rc = ocs_node_recv_bls_no_sit(node, seq);
}
break;
case FC_RCTL_FC4_DATA:
switch(hdr->type) {
case FC_TYPE_FCP:
if (hdr->info == FC_RCTL_INFO_UNSOL_CMD) {
if (node->fcp_enabled) {
if (sit_set) {
rc = ocs_dispatch_fcp_cmd(node, seq);
}else {
/* send the auto xfer ready command */
rc = ocs_dispatch_fcp_cmd_auto_xfer_rdy(node, seq);
}
} else {
rc = ocs_node_recv_fcp_cmd(node, seq);
}
} else if (hdr->info == FC_RCTL_INFO_SOL_DATA) {
if (sit_set) {
rc = ocs_dispatch_fcp_data(node, seq);
}
}
break;
case FC_TYPE_GS:
if (sit_set) {
rc = ocs_node_recv_ct_frame(node, seq);
}
break;
default:
break;
}
break;
}
} else {
node_printf(node, "Dropping frame hdr = %08x %08x %08x %08x %08x %08x\n",
ocs_htobe32(((uint32_t *)hdr)[0]),
ocs_htobe32(((uint32_t *)hdr)[1]),
ocs_htobe32(((uint32_t *)hdr)[2]),
ocs_htobe32(((uint32_t *)hdr)[3]),
ocs_htobe32(((uint32_t *)hdr)[4]),
ocs_htobe32(((uint32_t *)hdr)[5]));
}
return rc;
}
/**
* @ingroup unsol
* @brief Dispatch unsolicited FCP frames (RQ Pair).
*
* <h3 class="desc">Description</h3>
* Dispatch unsolicited FCP frames (called from the device node state machine).
*
* @param io Pointer to the IO context.
* @param task_management_flags Task management flags from the FCP_CMND frame.
* @param node Node that originated the frame.
* @param lun 32-bit LUN from FCP_CMND frame.
*
* @return Returns None.
*/
static void
ocs_dispatch_unsolicited_tmf(ocs_io_t *io, uint8_t task_management_flags, ocs_node_t *node, uint64_t lun)
{
uint32_t i;
struct {
uint32_t mask;
ocs_scsi_tmf_cmd_e cmd;
} tmflist[] = {
{FCP_QUERY_TASK_SET, OCS_SCSI_TMF_QUERY_TASK_SET},
{FCP_ABORT_TASK_SET, OCS_SCSI_TMF_ABORT_TASK_SET},
{FCP_CLEAR_TASK_SET, OCS_SCSI_TMF_CLEAR_TASK_SET},
{FCP_QUERY_ASYNCHRONOUS_EVENT, OCS_SCSI_TMF_QUERY_ASYNCHRONOUS_EVENT},
{FCP_LOGICAL_UNIT_RESET, OCS_SCSI_TMF_LOGICAL_UNIT_RESET},
{FCP_TARGET_RESET, OCS_SCSI_TMF_TARGET_RESET},
{FCP_CLEAR_ACA, OCS_SCSI_TMF_CLEAR_ACA}};
io->exp_xfer_len = 0; /* BUG 32235 */
for (i = 0; i < ARRAY_SIZE(tmflist); i ++) {
if (tmflist[i].mask & task_management_flags) {
io->tmf_cmd = tmflist[i].cmd;
ocs_scsi_recv_tmf(io, lun, tmflist[i].cmd, NULL, 0);
break;
}
}
if (i == ARRAY_SIZE(tmflist)) {
/* Not handled */
node_printf(node, "TMF x%x rejected\n", task_management_flags);
ocs_scsi_send_tmf_resp(io, OCS_SCSI_TMF_FUNCTION_REJECTED, NULL, ocs_fc_tmf_rejected_cb, NULL);
}
}
static int32_t
ocs_validate_fcp_cmd(ocs_t *ocs, ocs_hw_sequence_t *seq)
{
size_t exp_payload_len = 0;
fcp_cmnd_iu_t *cmnd = seq->payload->dma.virt;
exp_payload_len = sizeof(fcp_cmnd_iu_t) - 16 + cmnd->additional_fcp_cdb_length;
/*
* If we received less than FCP_CMND_IU bytes, assume that the frame is
* corrupted in some way and drop it. This was seen when jamming the FCTL
* fill bytes field.
*/
if (seq->payload->dma.len < exp_payload_len) {
fc_header_t *fchdr = seq->header->dma.virt;
ocs_log_debug(ocs, "dropping ox_id %04x with payload length (%zd) less than expected (%zd)\n",
ocs_be16toh(fchdr->ox_id), seq->payload->dma.len,
exp_payload_len);
return -1;
}
return 0;
}
static void
ocs_populate_io_fcp_cmd(ocs_io_t *io, fcp_cmnd_iu_t *cmnd, fc_header_t *fchdr, uint8_t sit)
{
uint32_t *fcp_dl;
io->init_task_tag = ocs_be16toh(fchdr->ox_id);
/* note, tgt_task_tag, hw_tag set when HW io is allocated */
fcp_dl = (uint32_t*)(&(cmnd->fcp_cdb_and_dl));
fcp_dl += cmnd->additional_fcp_cdb_length;
io->exp_xfer_len = ocs_be32toh(*fcp_dl);
io->transferred = 0;
/* The upper 7 bits of CS_CTL is the frame priority thru the SAN.
* Our assertion here is, the priority given to a frame containing
* the FCP cmd should be the priority given to ALL frames contained
* in that IO. Thus we need to save the incoming CS_CTL here.
*/
if (fc_be24toh(fchdr->f_ctl) & FC_FCTL_PRIORITY_ENABLE) {
io->cs_ctl = fchdr->cs_ctl;
} else {
io->cs_ctl = 0;
}
io->seq_init = sit;
}
static uint32_t
ocs_get_flags_fcp_cmd(fcp_cmnd_iu_t *cmnd)
{
uint32_t flags = 0;
switch (cmnd->task_attribute) {
case FCP_TASK_ATTR_SIMPLE:
flags |= OCS_SCSI_CMD_SIMPLE;
break;
case FCP_TASK_ATTR_HEAD_OF_QUEUE:
flags |= OCS_SCSI_CMD_HEAD_OF_QUEUE;
break;
case FCP_TASK_ATTR_ORDERED:
flags |= OCS_SCSI_CMD_ORDERED;
break;
case FCP_TASK_ATTR_ACA:
flags |= OCS_SCSI_CMD_ACA;
break;
case FCP_TASK_ATTR_UNTAGGED:
flags |= OCS_SCSI_CMD_UNTAGGED;
break;
}
if (cmnd->wrdata)
flags |= OCS_SCSI_CMD_DIR_IN;
if (cmnd->rddata)
flags |= OCS_SCSI_CMD_DIR_OUT;
return flags;
}
/**
* @ingroup unsol
* @brief Dispatch unsolicited FCP_CMND frame.
*
* <h3 class="desc">Description</h3>
* Dispatch unsolicited FCP_CMND frame. RQ Pair mode - always
* used for RQ Pair mode since first burst is not supported.
*
* @param node Node that originated the frame.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 if frame processed and RX buffers cleaned
* up appropriately, -1 if frame not handled and RX buffers need
* to be returned.
*/
static int32_t
ocs_dispatch_fcp_cmd(ocs_node_t *node, ocs_hw_sequence_t *seq)
{
ocs_t *ocs = node->ocs;
fc_header_t *fchdr = seq->header->dma.virt;
fcp_cmnd_iu_t *cmnd = NULL;
ocs_io_t *io = NULL;
fc_vm_header_t *vhdr;
uint8_t df_ctl;
uint64_t lun = UINT64_MAX;
int32_t rc = 0;
ocs_assert(seq->payload, -1);
cmnd = seq->payload->dma.virt;
/* perform FCP_CMND validation check(s) */
if (ocs_validate_fcp_cmd(ocs, seq)) {
return -1;
}
lun = CAM_EXTLUN_BYTE_SWIZZLE(be64dec(cmnd->fcp_lun));
if (lun == UINT64_MAX) {
return -1;
}
io = ocs_scsi_io_alloc(node, OCS_SCSI_IO_ROLE_RESPONDER);
if (io == NULL) {
uint32_t send_frame_capable;
/* If we have SEND_FRAME capability, then use it to send task set full or busy */
rc = ocs_hw_get(&ocs->hw, OCS_HW_SEND_FRAME_CAPABLE, &send_frame_capable);
if ((rc == 0) && send_frame_capable) {
rc = ocs_sframe_send_task_set_full_or_busy(node, seq);
if (rc) {
ocs_log_test(ocs, "ocs_sframe_send_task_set_full_or_busy failed: %d\n", rc);
}
return rc;
}
ocs_log_err(ocs, "IO allocation failed ox_id %04x\n", ocs_be16toh(fchdr->ox_id));
return -1;
}
io->hw_priv = seq->hw_priv;
/* Check if the CMD has vmheader. */
io->app_id = 0;
df_ctl = fchdr->df_ctl;
if (df_ctl & FC_DFCTL_DEVICE_HDR_16_MASK) {
uint32_t vmhdr_offset = 0;
/* Presence of VMID. Get the vm header offset. */
if (df_ctl & FC_DFCTL_ESP_HDR_MASK) {
vmhdr_offset += FC_DFCTL_ESP_HDR_SIZE;
ocs_log_err(ocs, "ESP Header present. Fix ESP Size.\n");
}
if (df_ctl & FC_DFCTL_NETWORK_HDR_MASK) {
vmhdr_offset += FC_DFCTL_NETWORK_HDR_SIZE;
}
vhdr = (fc_vm_header_t *) ((char *)fchdr + sizeof(fc_header_t) + vmhdr_offset);
io->app_id = ocs_be32toh(vhdr->src_vmid);
}
/* RQ pair, if we got here, SIT=1 */
ocs_populate_io_fcp_cmd(io, cmnd, fchdr, TRUE);
if (cmnd->task_management_flags) {
ocs_dispatch_unsolicited_tmf(io, cmnd->task_management_flags, node, lun);
} else {
uint32_t flags = ocs_get_flags_fcp_cmd(cmnd);
/* can return failure for things like task set full and UAs,
* no need to treat as a dropped frame if rc != 0
*/
ocs_scsi_recv_cmd(io, lun, cmnd->fcp_cdb,
sizeof(cmnd->fcp_cdb) +
(cmnd->additional_fcp_cdb_length * sizeof(uint32_t)),
flags);
}
/* successfully processed, now return RX buffer to the chip */
ocs_hw_sequence_free(&ocs->hw, seq);
return 0;
}
/**
* @ingroup unsol
* @brief Dispatch unsolicited FCP_CMND frame (auto xfer rdy).
*
* <h3 class="desc">Description</h3>
* Dispatch unsolicited FCP_CMND frame that is assisted with auto xfer ready.
*
* @param node Node that originated the frame.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 if frame processed and RX buffers cleaned
* up appropriately, -1 if frame not handled and RX buffers need
* to be returned.
*/
static int32_t
ocs_dispatch_fcp_cmd_auto_xfer_rdy(ocs_node_t *node, ocs_hw_sequence_t *seq)
{
ocs_t *ocs = node->ocs;
fc_header_t *fchdr = seq->header->dma.virt;
fcp_cmnd_iu_t *cmnd = NULL;
ocs_io_t *io = NULL;
uint64_t lun = UINT64_MAX;
int32_t rc = 0;
ocs_assert(seq->payload, -1);
cmnd = seq->payload->dma.virt;
/* perform FCP_CMND validation check(s) */
if (ocs_validate_fcp_cmd(ocs, seq)) {
return -1;
}
/* make sure first burst or auto xfer_rdy is enabled */
if (!seq->auto_xrdy) {
node_printf(node, "IO is not Auto Xfr Rdy assisted, dropping FCP_CMND\n");
return -1;
}
lun = CAM_EXTLUN_BYTE_SWIZZLE(be64dec(cmnd->fcp_lun));
/* TODO should there be a check here for an error? Why do any of the
* below if the LUN decode failed? */
io = ocs_scsi_io_alloc(node, OCS_SCSI_IO_ROLE_RESPONDER);
if (io == NULL) {
uint32_t send_frame_capable;
/* If we have SEND_FRAME capability, then use it to send task set full or busy */
rc = ocs_hw_get(&ocs->hw, OCS_HW_SEND_FRAME_CAPABLE, &send_frame_capable);
if ((rc == 0) && send_frame_capable) {
rc = ocs_sframe_send_task_set_full_or_busy(node, seq);
if (rc) {
ocs_log_test(ocs, "ocs_sframe_send_task_set_full_or_busy failed: %d\n", rc);
}
return rc;
}
ocs_log_err(ocs, "IO allocation failed ox_id %04x\n", ocs_be16toh(fchdr->ox_id));
return -1;
}
io->hw_priv = seq->hw_priv;
/* RQ pair, if we got here, SIT=0 */
ocs_populate_io_fcp_cmd(io, cmnd, fchdr, FALSE);
if (cmnd->task_management_flags) {
/* first burst command better not be a TMF */
ocs_log_err(ocs, "TMF flags set 0x%x\n", cmnd->task_management_flags);
ocs_scsi_io_free(io);
return -1;
} else {
uint32_t flags = ocs_get_flags_fcp_cmd(cmnd);
/* activate HW IO */
ocs_hw_io_activate_port_owned(&ocs->hw, seq->hio);
io->hio = seq->hio;
seq->hio->ul_io = io;
io->tgt_task_tag = seq->hio->indicator;
/* Note: Data buffers are received in another call */
ocs_scsi_recv_cmd_first_burst(io, lun, cmnd->fcp_cdb,
sizeof(cmnd->fcp_cdb) +
(cmnd->additional_fcp_cdb_length * sizeof(uint32_t)),
flags, NULL, 0);
}
/* FCP_CMND processed, return RX buffer to the chip */
ocs_hw_sequence_free(&ocs->hw, seq);
return 0;
}
/**
* @ingroup unsol
* @brief Dispatch FCP data frames for auto xfer ready.
*
* <h3 class="desc">Description</h3>
* Dispatch unsolicited FCP data frames (auto xfer ready)
* containing sequence initiative transferred (SIT=1).
*
* @param node Node that originated the frame.
* @param seq Header/payload sequence buffers.
*
* @return Returns 0 if frame processed and RX buffers cleaned
* up appropriately, -1 if frame not handled.
*/
static int32_t
ocs_dispatch_fcp_data(ocs_node_t *node, ocs_hw_sequence_t *seq)
{
ocs_t *ocs = node->ocs;
ocs_hw_t *hw = &ocs->hw;
ocs_hw_io_t *hio = seq->hio;
ocs_io_t *io;
ocs_dma_t fburst[1];
ocs_assert(seq->payload, -1);
ocs_assert(hio, -1);
io = hio->ul_io;
if (io == NULL) {
ocs_log_err(ocs, "data received for NULL io, xri=0x%x\n",
hio->indicator);
return -1;
}
/*
* We only support data completions for auto xfer ready. Make sure
* this is a port owned XRI.
*/
if (!ocs_hw_is_io_port_owned(hw, seq->hio)) {
ocs_log_err(ocs, "data received for host owned XRI, xri=0x%x\n",
hio->indicator);
return -1;
}
/* For error statuses, pass the error to the target back end */
if (seq->status != OCS_HW_UNSOL_SUCCESS) {
ocs_log_err(ocs, "data with status 0x%x received, xri=0x%x\n",
seq->status, hio->indicator);
/*
* In this case, there is an existing, in-use HW IO that
* first may need to be aborted. Then, the backend will be
* notified of the error while waiting for the data.
*/
ocs_port_owned_abort(ocs, seq->hio);
/*
* HW IO has already been allocated and is waiting for data.
* Need to tell backend that an error has occurred.
*/
ocs_scsi_recv_cmd_first_burst(io, 0, NULL, 0, OCS_SCSI_FIRST_BURST_ERR, NULL, 0);
return -1;
}
/* sequence initiative has been transferred */
io->seq_init = 1;
/* convert the array of pointers to the correct type, to send to backend */
fburst[0] = seq->payload->dma;
/* the amount of first burst data was saved as "acculated sequence length" */
io->transferred = seq->payload->dma.len;
if (ocs_scsi_recv_cmd_first_burst(io, 0, NULL, 0, 0,
fburst, io->transferred)) {
ocs_log_err(ocs, "error passing first burst, xri=0x%x, oxid=0x%x\n",
hio->indicator, io->init_task_tag);
}
/* Free the header and all the accumulated payload buffers */
ocs_hw_sequence_free(&ocs->hw, seq);
return 0;
}
/**
* @ingroup unsol
* @brief Handle the callback for the TMF FUNCTION_REJECTED response.
*
* <h3 class="desc">Description</h3>
* Handle the callback of a send TMF FUNCTION_REJECTED response request.
*
* @param io Pointer to the IO context.
* @param scsi_status Status of the response.
* @param flags Callback flags.
* @param arg Callback argument.
*
* @return Returns 0 on success, or a negative error value on failure.
*/
static int32_t
ocs_fc_tmf_rejected_cb(ocs_io_t *io, ocs_scsi_io_status_e scsi_status, uint32_t flags, void *arg)
{
ocs_scsi_io_free(io);
return 0;
}
/**
* @brief Return next FC frame on node->pend_frames list
*
* The next FC frame on the node->pend_frames list is returned, or NULL
* if the list is empty.
*
* @param pend_list Pending list to be purged.
* @param list_lock Lock that protects pending list.
*
* @return Returns pointer to the next FC frame, or NULL if the pending frame list
* is empty.
*/
static ocs_hw_sequence_t *
ocs_frame_next(ocs_list_t *pend_list, ocs_lock_t *list_lock)
{
ocs_hw_sequence_t *frame = NULL;
ocs_lock(list_lock);
frame = ocs_list_remove_head(pend_list);
ocs_unlock(list_lock);
return frame;
}
/**
* @brief Process send fcp response frame callback
*
* The function is called when the send FCP response posting has completed. Regardless
* of the outcome, the sequence is freed.
*
* @param arg Pointer to originator frame sequence.
* @param cqe Pointer to completion queue entry.
* @param status Status of operation.
*
* @return None.
*/
static void
ocs_sframe_common_send_cb(void *arg, uint8_t *cqe, int32_t status)
{
ocs_hw_send_frame_context_t *ctx = arg;
ocs_hw_t *hw = ctx->hw;
/* Free WQ completion callback */
ocs_hw_reqtag_free(hw, ctx->wqcb);
/* Free sequence */
ocs_hw_sequence_free(hw, ctx->seq);
}
/**
* @brief Send a frame, common code
*
* A frame is sent using SEND_FRAME, the R_CTL/F_CTL/TYPE may be specified, the payload is
* sent as a single frame.
*
* Memory resources are allocated from RQ buffers contained in the passed in sequence data.
*
* @param node Pointer to node object.
* @param seq Pointer to sequence object.
* @param r_ctl R_CTL value to place in FC header.
* @param info INFO value to place in FC header.
* @param f_ctl F_CTL value to place in FC header.
* @param type TYPE value to place in FC header.
* @param payload Pointer to payload data
* @param payload_len Length of payload in bytes.
*
* @return Returns 0 on success, or a negative error code value on failure.
*/
static int32_t
ocs_sframe_common_send(ocs_node_t *node, ocs_hw_sequence_t *seq, uint8_t r_ctl, uint8_t info, uint32_t f_ctl,
uint8_t type, void *payload, uint32_t payload_len)
{
ocs_t *ocs = node->ocs;
ocs_hw_t *hw = &ocs->hw;
ocs_hw_rtn_e rc = 0;
fc_header_t *behdr = seq->header->dma.virt;
fc_header_le_t hdr;
uint32_t s_id = fc_be24toh(behdr->s_id);
uint32_t d_id = fc_be24toh(behdr->d_id);
uint16_t ox_id = ocs_be16toh(behdr->ox_id);
uint16_t rx_id = ocs_be16toh(behdr->rx_id);
ocs_hw_send_frame_context_t *ctx;
uint32_t heap_size = seq->payload->dma.size;
uintptr_t heap_phys_base = seq->payload->dma.phys;
uint8_t *heap_virt_base = seq->payload->dma.virt;
uint32_t heap_offset = 0;
/* Build the FC header reusing the RQ header DMA buffer */
ocs_memset(&hdr, 0, sizeof(hdr));
hdr.d_id = s_id; /* send it back to whomever sent it to us */
hdr.r_ctl = r_ctl;
hdr.info = info;
hdr.s_id = d_id;
hdr.cs_ctl = 0;
hdr.f_ctl = f_ctl;
hdr.type = type;
hdr.seq_cnt = 0;
hdr.df_ctl = 0;
/*
* send_frame_seq_id is an atomic, we just let it increment, while storing only
* the low 8 bits to hdr->seq_id
*/
hdr.seq_id = (uint8_t) ocs_atomic_add_return(&hw->send_frame_seq_id, 1);
hdr.rx_id = rx_id;
hdr.ox_id = ox_id;
hdr.parameter = 0;
/* Allocate and fill in the send frame request context */
ctx = (void*)(heap_virt_base + heap_offset);
heap_offset += sizeof(*ctx);
ocs_assert(heap_offset < heap_size, -1);
ocs_memset(ctx, 0, sizeof(*ctx));
/* Save sequence */
ctx->seq = seq;
/* Allocate a response payload DMA buffer from the heap */
ctx->payload.phys = heap_phys_base + heap_offset;
ctx->payload.virt = heap_virt_base + heap_offset;
ctx->payload.size = payload_len;
ctx->payload.len = payload_len;
heap_offset += payload_len;
ocs_assert(heap_offset <= heap_size, -1);
/* Copy the payload in */
ocs_memcpy(ctx->payload.virt, payload, payload_len);
/* Send */
rc = ocs_hw_send_frame(&ocs->hw, (void*)&hdr, FC_SOFI3, FC_EOFT, &ctx->payload, ctx,
ocs_sframe_common_send_cb, ctx);
if (rc) {
ocs_log_test(ocs, "ocs_hw_send_frame failed: %d\n", rc);
}
return rc ? -1 : 0;
}
/**
* @brief Send FCP response using SEND_FRAME
*
* The FCP response is send using the SEND_FRAME function.
*
* @param node Pointer to node object.
* @param seq Pointer to inbound sequence.
* @param rsp Pointer to response data.
* @param rsp_len Length of response data, in bytes.
*
* @return Returns 0 on success, or a negative error code value on failure.
*/
static int32_t
ocs_sframe_send_fcp_rsp(ocs_node_t *node, ocs_hw_sequence_t *seq, void *rsp, uint32_t rsp_len)
{
return ocs_sframe_common_send(node, seq,
FC_RCTL_FC4_DATA,
FC_RCTL_INFO_CMD_STATUS,
FC_FCTL_EXCHANGE_RESPONDER |
FC_FCTL_LAST_SEQUENCE |
FC_FCTL_END_SEQUENCE |
FC_FCTL_SEQUENCE_INITIATIVE,
FC_TYPE_FCP,
rsp, rsp_len);
}
/**
* @brief Send task set full response
*
* Return a task set full or busy response using send frame.
*
* @param node Pointer to node object.
* @param seq Pointer to originator frame sequence.
*
* @return Returns 0 on success, or a negative error code value on failure.
*/
static int32_t
ocs_sframe_send_task_set_full_or_busy(ocs_node_t *node, ocs_hw_sequence_t *seq)
{
fcp_rsp_iu_t fcprsp;
fcp_cmnd_iu_t *fcpcmd = seq->payload->dma.virt;
uint32_t *fcp_dl_ptr;
uint32_t fcp_dl;
int32_t rc = 0;
/* extract FCP_DL from FCP command*/
fcp_dl_ptr = (uint32_t*)(&(fcpcmd->fcp_cdb_and_dl));
fcp_dl_ptr += fcpcmd->additional_fcp_cdb_length;
fcp_dl = ocs_be32toh(*fcp_dl_ptr);
/* construct task set full or busy response */
ocs_memset(&fcprsp, 0, sizeof(fcprsp));
ocs_lock(&node->active_ios_lock);
fcprsp.scsi_status = ocs_list_empty(&node->active_ios) ? SCSI_STATUS_BUSY : SCSI_STATUS_TASK_SET_FULL;
ocs_unlock(&node->active_ios_lock);
*((uint32_t*)&fcprsp.fcp_resid) = fcp_dl;
/* send it using send_frame */
rc = ocs_sframe_send_fcp_rsp(node, seq, &fcprsp, sizeof(fcprsp) - sizeof(fcprsp.data));
if (rc) {
ocs_log_test(node->ocs, "ocs_sframe_send_fcp_rsp failed: %d\n", rc);
}
return rc;
}
/**
* @brief Send BA_ACC using sent frame
*
* A BA_ACC is sent using SEND_FRAME
*
* @param node Pointer to node object.
* @param seq Pointer to originator frame sequence.
*
* @return Returns 0 on success, or a negative error code value on failure.
*/
int32_t
ocs_sframe_send_bls_acc(ocs_node_t *node, ocs_hw_sequence_t *seq)
{
fc_header_t *behdr = seq->header->dma.virt;
uint16_t ox_id = ocs_be16toh(behdr->ox_id);
uint16_t rx_id = ocs_be16toh(behdr->rx_id);
fc_ba_acc_payload_t acc = {0};
acc.ox_id = ocs_htobe16(ox_id);
acc.rx_id = ocs_htobe16(rx_id);
acc.low_seq_cnt = UINT16_MAX;
acc.high_seq_cnt = UINT16_MAX;
return ocs_sframe_common_send(node, seq,
FC_RCTL_BLS,
FC_RCTL_INFO_UNSOL_DATA,
FC_FCTL_EXCHANGE_RESPONDER |
FC_FCTL_LAST_SEQUENCE |
FC_FCTL_END_SEQUENCE,
FC_TYPE_BASIC_LINK,
&acc, sizeof(acc));
}