freebsd-nq/sys/dev/twa/tw_cl_misc.c
Vinod Kashyap ff1625c61d twa corresponding to the 9.3.0.1 release on the 3ware website. This driver has
support for the 9xxxSX controllers, along with the earlier 9xxxS series
controllers.
2005-11-08 22:51:43 +00:00

1092 lines
32 KiB
C

/*
* Copyright (c) 2004-05 Applied Micro Circuits Corporation.
* Copyright (c) 2004-05 Vinod Kashyap
* All rights reserved.
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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.
*
* $FreeBSD$
*/
/*
* AMCC'S 3ware driver for 9000 series storage controllers.
*
* Author: Vinod Kashyap
*/
/*
* Common Layer miscellaneous functions.
*/
#include "tw_osl_share.h"
#include "tw_cl_share.h"
#include "tw_cl_fwif.h"
#include "tw_cl_ioctl.h"
#include "tw_cl.h"
#include "tw_cl_externs.h"
#include "tw_osl_ioctl.h"
/* AEN severity table. */
TW_INT8 *tw_cli_severity_string_table[] = {
"None",
TW_CL_SEVERITY_ERROR_STRING,
TW_CL_SEVERITY_WARNING_STRING,
TW_CL_SEVERITY_INFO_STRING,
TW_CL_SEVERITY_DEBUG_STRING,
""
};
/*
* Function name: tw_cli_drain_complete_queue
* Description: This function gets called during a controller reset.
* It errors back to the OS Layer, all those requests that
* are in the complete queue, at the time of the reset.
* Any CL internal requests will be simply freed.
*
* Input: ctlr -- ptr to CL internal ctlr context
* Output: None
* Return value: None
*/
TW_VOID
tw_cli_drain_complete_queue(struct tw_cli_ctlr_context *ctlr)
{
struct tw_cli_req_context *req;
struct tw_cl_req_packet *req_pkt;
tw_cli_dbg_printf(3, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
/* Walk the busy queue. */
while ((req = tw_cli_req_q_remove_head(ctlr, TW_CLI_COMPLETE_Q))) {
if (req->flags & TW_CLI_REQ_FLAGS_INTERNAL) {
/*
* It's an internal request. Set the appropriate
* error and call the CL internal callback if there's
* one. If the request originator is polling for
* completion, he should be checking req->error to
* determine that the request did not go through.
* The request originators are responsible for the
* clean-up.
*/
req->error_code = TW_CL_ERR_REQ_BUS_RESET;
if (req->tw_cli_callback)
req->tw_cli_callback(req);
} else {
if ((req_pkt = req->orig_req)) {
/* It's a SCSI request. Complete it. */
tw_cli_dbg_printf(2, ctlr->ctlr_handle,
tw_osl_cur_func(),
"Completing complete request %p "
"on reset",
req);
req_pkt->status = TW_CL_ERR_REQ_BUS_RESET;
req_pkt->tw_osl_callback(req->req_handle);
}
tw_cli_req_q_insert_tail(req, TW_CLI_FREE_Q);
}
}
}
/*
* Function name: tw_cli_drain_busy_queue
* Description: This function gets called during a controller reset.
* It errors back to the OS Layer, all those requests that
* were pending with the firmware, at the time of the
* reset.
*
* Input: ctlr -- ptr to CL internal ctlr context
* Output: None
* Return value: None
*/
TW_VOID
tw_cli_drain_busy_queue(struct tw_cli_ctlr_context *ctlr)
{
struct tw_cli_req_context *req;
struct tw_cl_req_packet *req_pkt;
tw_cli_dbg_printf(3, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
/* Walk the busy queue. */
while ((req = tw_cli_req_q_remove_head(ctlr, TW_CLI_BUSY_Q))) {
if (req->flags & TW_CLI_REQ_FLAGS_INTERNAL) {
/*
* It's an internal request. Set the appropriate
* error and call the CL internal callback if there's
* one. If the request originator is polling for
* completion, he should be checking req->error to
* determine that the request did not go through.
* The request originators are responsible for the
* clean-up.
*/
req->error_code = TW_CL_ERR_REQ_BUS_RESET;
if (req->tw_cli_callback)
req->tw_cli_callback(req);
} else {
if ((req_pkt = req->orig_req)) {
/* It's a SCSI request. Complete it. */
tw_cli_dbg_printf(2, ctlr->ctlr_handle,
tw_osl_cur_func(),
"Completing busy request %p on reset",
req);
req_pkt->status = TW_CL_ERR_REQ_BUS_RESET;
req_pkt->tw_osl_callback(req->req_handle);
}
tw_cli_req_q_insert_tail(req, TW_CLI_FREE_Q);
}
}
}
/*
* Function name: tw_cli_drain_pending_queue
* Description: This function gets called during a controller reset.
* It errors back to the OS Layer, all those requests that
* were in the pending queue, at the time of the reset.
*
* Input: ctlr -- ptr to CL internal ctlr context
* Output: None
* Return value: None
*/
TW_VOID
tw_cli_drain_pending_queue(struct tw_cli_ctlr_context *ctlr)
{
struct tw_cli_req_context *req;
struct tw_cl_req_packet *req_pkt;
tw_cli_dbg_printf(3, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
/*
* Pull requests off the pending queue, and complete them.
*/
while ((req = tw_cli_req_q_remove_head(ctlr, TW_CLI_PENDING_Q))) {
if (req->flags & TW_CLI_REQ_FLAGS_INTERNAL) {
/*
* It's an internal request. Set the appropriate
* error and call the CL internal callback if there's
* one. If the request originator is polling for
* completion, he should be checking req->error to
* determine that the request did not go through.
* The request originators are responsible for the
* clean-up.
*/
req->error_code = TW_CL_ERR_REQ_BUS_RESET;
if (req->tw_cli_callback)
req->tw_cli_callback(req);
} else {
if ((req_pkt = req->orig_req)) {
/* It's an external request. Complete it. */
tw_cli_dbg_printf(2, ctlr->ctlr_handle,
tw_osl_cur_func(),
"Completing pending request %p "
"on reset", req);
req_pkt->status = TW_CL_ERR_REQ_BUS_RESET;
req_pkt->tw_osl_callback(req->req_handle);
}
tw_cli_req_q_insert_tail(req, TW_CLI_FREE_Q);
}
}
}
/*
* Function name: tw_cli_drain_response_queue
* Description: Drain the controller response queue.
*
* Input: ctlr -- ptr to per ctlr structure
* Output: None
* Return value: 0 -- success
* non-zero-- failure
*/
TW_INT32
tw_cli_drain_response_queue(struct tw_cli_ctlr_context *ctlr)
{
TW_UINT32 resp;
TW_UINT32 status_reg;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
for (;;) {
status_reg = TW_CLI_READ_STATUS_REGISTER(ctlr->ctlr_handle);
if (tw_cli_check_ctlr_state(ctlr, status_reg))
return(TW_OSL_EGENFAILURE);
if (status_reg & TWA_STATUS_RESPONSE_QUEUE_EMPTY)
return(TW_OSL_ESUCCESS); /* no more response queue entries */
resp = TW_CLI_READ_RESPONSE_QUEUE(ctlr->ctlr_handle);
}
}
/*
* Function name: tw_cli_find_response
* Description: Find a particular response in the ctlr response queue.
*
* Input: ctlr -- ptr to per ctlr structure
* req_id -- request id of the response to look for
* Output: None
* Return value: 0 -- success
* non-zero-- failure
*/
TW_INT32
tw_cli_find_response(struct tw_cli_ctlr_context *ctlr, TW_INT32 req_id)
{
TW_UINT32 resp;
TW_INT32 resp_id;
TW_UINT32 status_reg;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
for (;;) {
status_reg = TW_CLI_READ_STATUS_REGISTER(ctlr->ctlr_handle);
if (tw_cli_check_ctlr_state(ctlr, status_reg))
return(TW_OSL_EGENFAILURE);
if (status_reg & TWA_STATUS_RESPONSE_QUEUE_EMPTY)
return(TW_OSL_ENOTTY); /* no more response queue entries */
if (ctlr->device_id == TW_CL_DEVICE_ID_9K) {
resp = TW_CLI_READ_RESPONSE_QUEUE(ctlr->ctlr_handle);
resp_id = GET_RESP_ID(resp);
} else {
resp = TW_CLI_READ_LARGE_RESPONSE_QUEUE(
ctlr->ctlr_handle);
resp_id = GET_LARGE_RESP_ID(resp);
}
if (resp_id == req_id)
return(TW_OSL_ESUCCESS); /* found the req_id */
}
}
/*
* Function name: tw_cli_drain_aen_queue
* Description: Fetches all un-retrieved AEN's posted by fw.
*
* Input: ctlr -- ptr to CL internal ctlr context
* Output: None
* Return value: 0 -- success
* non-zero-- failure
*/
TW_INT32
tw_cli_drain_aen_queue(struct tw_cli_ctlr_context *ctlr)
{
struct tw_cli_req_context *req;
struct tw_cl_command_header *cmd_hdr;
TW_TIME end_time;
TW_UINT16 aen_code;
TW_INT32 error;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
for (;;) {
if ((req = tw_cli_get_request(ctlr
#ifdef TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST
, TW_CL_NULL
#endif /* TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST */
)) == TW_CL_NULL) {
error = TW_OSL_EBUSY;
break;
}
#ifdef TW_OSL_DMA_MEM_ALLOC_PER_REQUEST
req->cmd_pkt = ctlr->cmd_pkt_buf;
req->cmd_pkt_phys = ctlr->cmd_pkt_phys;
tw_osl_memzero(req->cmd_pkt,
sizeof(struct tw_cl_command_header) +
28 /* max bytes before sglist */);
#endif /* TW_OSL_DMA_MEM_ALLOC_PER_REQUEST */
req->flags |= TW_CLI_REQ_FLAGS_INTERNAL;
req->tw_cli_callback = TW_CL_NULL;
if ((error = tw_cli_send_scsi_cmd(req,
0x03 /* REQUEST_SENSE */))) {
tw_cli_dbg_printf(1, ctlr->ctlr_handle,
tw_osl_cur_func(),
"Cannot send command to fetch aen");
break;
}
end_time = tw_osl_get_local_time() +
TW_CLI_REQUEST_TIMEOUT_PERIOD;
do {
if ((error = req->error_code))
/*
* This will take care of completion due to
* a reset, or a failure in
* tw_cli_submit_pending_queue.
*/
goto out;
tw_cli_process_resp_intr(req->ctlr);
if ((req->state != TW_CLI_REQ_STATE_BUSY) &&
(req->state != TW_CLI_REQ_STATE_PENDING))
break;
} while (tw_osl_get_local_time() <= end_time);
if (req->state != TW_CLI_REQ_STATE_COMPLETE) {
error = TW_OSL_ETIMEDOUT;
break;
}
if ((error = req->cmd_pkt->command.cmd_pkt_9k.status)) {
cmd_hdr = &req->cmd_pkt->cmd_hdr;
tw_cli_create_ctlr_event(ctlr,
TW_CL_MESSAGE_SOURCE_CONTROLLER_ERROR,
cmd_hdr);
break;
}
aen_code = tw_cli_manage_aen(ctlr, req);
if (aen_code == TWA_AEN_QUEUE_EMPTY)
break;
if (aen_code == TWA_AEN_SYNC_TIME_WITH_HOST)
continue;
ctlr->state &= ~TW_CLI_CTLR_STATE_INTERNAL_REQ_BUSY;
tw_cli_req_q_insert_tail(req, TW_CLI_FREE_Q);
}
out:
if (req) {
if (req->data)
ctlr->state &= ~TW_CLI_CTLR_STATE_INTERNAL_REQ_BUSY;
tw_cli_req_q_insert_tail(req, TW_CLI_FREE_Q);
}
return(error);
}
/*
* Function name: tw_cli_find_aen
* Description: Reports whether a given AEN ever occurred.
*
* Input: ctlr -- ptr to CL internal ctlr context
* aen_code-- AEN to look for
* Output: None
* Return value: 0 -- success
* non-zero-- failure
*/
TW_INT32
tw_cli_find_aen(struct tw_cli_ctlr_context *ctlr, TW_UINT16 aen_code)
{
TW_UINT32 last_index;
TW_INT32 i;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
if (ctlr->aen_q_wrapped)
last_index = ctlr->aen_head;
else
last_index = 0;
i = ctlr->aen_head;
do {
i = (i + ctlr->max_aens_supported - 1) %
ctlr->max_aens_supported;
if (ctlr->aen_queue[i].aen_code == aen_code)
return(TW_OSL_ESUCCESS);
} while (i != last_index);
return(TW_OSL_EGENFAILURE);
}
/*
* Function name: tw_cli_poll_status
* Description: Poll for a given status to show up in the firmware
* status register.
*
* Input: ctlr -- ptr to CL internal ctlr context
* status -- status to look for
* timeout -- max # of seconds to wait before giving up
* Output: None
* Return value: 0 -- success
* non-zero-- failure
*/
TW_INT32
tw_cli_poll_status(struct tw_cli_ctlr_context *ctlr, TW_UINT32 status,
TW_UINT32 timeout)
{
TW_TIME end_time;
TW_UINT32 status_reg;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
end_time = tw_osl_get_local_time() + timeout;
do {
status_reg = TW_CLI_READ_STATUS_REGISTER(ctlr->ctlr_handle);
if ((status_reg & status) == status)
/* got the required bit(s) */
return(TW_OSL_ESUCCESS);
/*
* The OSL should not define TW_OSL_CAN_SLEEP if it calls
* tw_cl_deferred_interrupt from within the ISR and not a
* lower interrupt level, since, in that case, we might end
* up here, and try to sleep (within an ISR).
*/
#ifndef TW_OSL_CAN_SLEEP
/* OSL doesn't support sleeping; will spin. */
tw_osl_delay(1000);
#else /* TW_OSL_CAN_SLEEP */
#if 0
/* Will spin if initializing, sleep otherwise. */
if (!(ctlr->state & TW_CLI_CTLR_STATE_ACTIVE))
tw_osl_delay(1000);
else
tw_osl_sleep(ctlr->ctlr_handle,
&(ctlr->sleep_handle), 1 /* ms */);
#else /* #if 0 */
/*
* Will always spin for now (since reset holds a spin lock).
* We could free io_lock after the call to TW_CLI_SOFT_RESET,
* so we could sleep here. To block new requests (since
* the lock will have been released) we could use the
* ...RESET_IN_PROGRESS flag. Need to revisit.
*/
tw_osl_delay(1000);
#endif /* #if 0 */
#endif /* TW_OSL_CAN_SLEEP */
} while (tw_osl_get_local_time() <= end_time);
return(TW_OSL_ETIMEDOUT);
}
/*
* Function name: tw_cl_create_event
* Description: Creates and queues ctlr/CL/OSL AEN's to be
* supplied to user-space tools on request.
* Also notifies OS Layer.
* Input: ctlr -- ptr to CL internal ctlr context
* queue_event-- TW_CL_TRUE --> queue event;
* TW_CL_FALSE--> don't queue event
* (simply notify OSL)
* event_src -- source of event
* event_code -- AEN/error code
* severity -- severity of event
* severity_str--Text description of severity
* event_desc -- standard string related to the event/error
* event_specific_desc -- format string for additional
* info about the event
* ... -- additional arguments conforming to the format
* specified by event_specific_desc
* Output: None
* Return value: None
*/
TW_VOID
tw_cl_create_event(struct tw_cl_ctlr_handle *ctlr_handle,
TW_UINT8 queue_event, TW_UINT8 event_src, TW_UINT16 event_code,
TW_UINT8 severity, TW_UINT8 *severity_str, TW_UINT8 *event_desc,
TW_UINT8 *event_specific_desc, ...)
{
struct tw_cli_ctlr_context *ctlr = ctlr_handle->cl_ctlr_ctxt;
struct tw_cl_event_packet event_pkt;
struct tw_cl_event_packet *event;
TW_UINT32 aen_head;
va_list ap;
tw_cli_dbg_printf(8, ctlr_handle, tw_osl_cur_func(), "entered");
if ((ctlr) && (queue_event)) {
/* Protect access to ctlr->aen_head. */
tw_osl_get_lock(ctlr_handle, ctlr->gen_lock);
aen_head = ctlr->aen_head;
ctlr->aen_head = (aen_head + 1) % ctlr->max_aens_supported;
/* Queue the event. */
event = &(ctlr->aen_queue[aen_head]);
tw_osl_memzero(event->parameter_data,
sizeof(event->parameter_data));
if (event->retrieved == TW_CL_AEN_NOT_RETRIEVED)
ctlr->aen_q_overflow = TW_CL_TRUE;
event->sequence_id = ++(ctlr->aen_cur_seq_id);
if ((aen_head + 1) == ctlr->max_aens_supported) {
tw_cli_dbg_printf(4, ctlr->ctlr_handle,
tw_osl_cur_func(), "AEN queue wrapped");
ctlr->aen_q_wrapped = TW_CL_TRUE;
}
/* Free access to ctlr->aen_head. */
tw_osl_free_lock(ctlr_handle, ctlr->gen_lock);
} else {
event = &event_pkt;
tw_osl_memzero(event, sizeof(struct tw_cl_event_packet));
}
event->event_src = event_src;
event->time_stamp_sec = (TW_UINT32)tw_osl_get_local_time();
event->aen_code = event_code;
event->severity = severity;
tw_osl_strcpy(event->severity_str, severity_str);
event->retrieved = TW_CL_AEN_NOT_RETRIEVED;
va_start(ap, event_specific_desc);
tw_osl_vsprintf(event->parameter_data, event_specific_desc, ap);
va_end(ap);
event->parameter_len =
(TW_UINT8)(tw_osl_strlen(event->parameter_data));
tw_osl_strcpy(event->parameter_data + event->parameter_len + 1,
event_desc);
event->parameter_len += (1 + tw_osl_strlen(event_desc));
tw_cli_dbg_printf(4, ctlr_handle, tw_osl_cur_func(),
"event = %x %x %x %x %x %x %x\n %s",
event->sequence_id,
event->time_stamp_sec,
event->aen_code,
event->severity,
event->retrieved,
event->repeat_count,
event->parameter_len,
event->parameter_data);
tw_osl_notify_event(ctlr_handle, event);
}
/*
* Function name: tw_cli_get_request
* Description: Gets a request pkt from the free queue.
*
* Input: ctlr -- ptr to CL internal ctlr context
* req_pkt -- ptr to OSL built req_pkt, if there's one
* Output: None
* Return value: ptr to request pkt -- success
* TW_CL_NULL -- failure
*/
struct tw_cli_req_context *
tw_cli_get_request(struct tw_cli_ctlr_context *ctlr
#ifdef TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST
, struct tw_cl_req_packet *req_pkt
#endif /* TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST */
)
{
struct tw_cli_req_context *req;
tw_cli_dbg_printf(4, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
#ifdef TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST
if (req_pkt) {
if (ctlr->num_free_req_ids == 0)
return(TW_CL_NULL);
ctlr->num_free_req_ids--;
req = (struct tw_cli_req_context *)(req_pkt->non_dma_mem);
req->ctlr = ctlr;
req->request_id = ctlr->free_req_ids[ctlr->free_req_head];
ctlr->busy_reqs[req->request_id] = req;
ctlr->free_req_head = (ctlr->free_req_head + 1) %
(ctlr->max_simult_reqs - 1);
} else
#endif /* TW_OSL_NON_DMA_MEM_ALLOC_PER_REQUEST */
{
/* Get a free request packet. */
req = tw_cli_req_q_remove_head(ctlr, TW_CLI_FREE_Q);
}
/* Initialize some fields to their defaults. */
if (req) {
req->req_handle = TW_CL_NULL;
req->data = TW_CL_NULL;
req->length = 0;
req->data_phys = 0;
req->state = TW_CLI_REQ_STATE_INIT; /* req being initialized */
req->flags = 0;
req->error_code = 0;
req->orig_req = TW_CL_NULL;
req->tw_cli_callback = TW_CL_NULL;
#ifndef TW_OSL_DMA_MEM_ALLOC_PER_REQUEST
/*
* Look at the status field in the command packet to see how
* it completed the last time it was used, and zero out only
* the portions that might have changed. Note that we don't
* care to zero out the sglist.
*/
if (req->cmd_pkt->command.cmd_pkt_9k.status)
tw_osl_memzero(req->cmd_pkt,
sizeof(struct tw_cl_command_header) +
28 /* max bytes before sglist */);
else
tw_osl_memzero(&(req->cmd_pkt->command),
28 /* max bytes before sglist */);
#endif /* TW_OSL_DMA_MEM_ALLOC_PER_REQUEST */
}
return(req);
}
/*
* Function name: tw_cli_dbg_printf
* Description: Calls OSL print function if dbg_level is appropriate
*
* Input: dbg_level -- Determines whether or not to print
* ctlr_handle -- controller handle
* cur_func -- text name of calling function
* fmt -- format string for the arguments to follow
* ... -- variable number of arguments, to be printed
* based on the fmt string
* Output: None
* Return value: None
*/
TW_VOID
tw_cli_dbg_printf(TW_UINT8 dbg_level,
struct tw_cl_ctlr_handle *ctlr_handle, const TW_INT8 *cur_func,
TW_INT8 *fmt, ...)
{
#ifdef TW_OSL_DEBUG
TW_INT8 print_str[256];
va_list ap;
tw_osl_memzero(print_str, 256);
if (dbg_level <= TW_OSL_DEBUG_LEVEL_FOR_CL) {
tw_osl_sprintf(print_str, "%s: ", cur_func);
va_start(ap, fmt);
tw_osl_vsprintf(print_str + tw_osl_strlen(print_str), fmt, ap);
va_end(ap);
tw_osl_strcpy(print_str + tw_osl_strlen(print_str), "\n");
tw_osl_dbg_printf(ctlr_handle, print_str);
}
#endif /* TW_OSL_DEBUG */
}
/*
* Function name: tw_cli_notify_ctlr_info
* Description: Notify OSL of controller info (fw/BIOS versions, etc.).
*
* Input: ctlr -- ptr to CL internal ctlr context
* Output: None
* Return value: None
*/
TW_VOID
tw_cli_notify_ctlr_info(struct tw_cli_ctlr_context *ctlr)
{
TW_INT8 fw_ver[16];
TW_INT8 bios_ver[16];
TW_INT8 ctlr_model[16];
TW_INT32 error[3];
TW_UINT8 num_ports = 0;
tw_cli_dbg_printf(5, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
/* Get the port count. */
error[0] = tw_cli_get_param(ctlr, TWA_PARAM_CONTROLLER_TABLE,
TWA_PARAM_CONTROLLER_PORT_COUNT, &num_ports,
1, TW_CL_NULL);
/* Get the firmware and BIOS versions. */
error[0] = tw_cli_get_param(ctlr, TWA_PARAM_VERSION_TABLE,
TWA_PARAM_VERSION_FW, fw_ver, 16, TW_CL_NULL);
error[1] = tw_cli_get_param(ctlr, TWA_PARAM_VERSION_TABLE,
TWA_PARAM_VERSION_BIOS, bios_ver, 16, TW_CL_NULL);
error[2] = tw_cli_get_param(ctlr, TWA_PARAM_VERSION_TABLE,
TWA_PARAM_CTLR_MODEL, ctlr_model, 16, TW_CL_NULL);
tw_cl_create_event(ctlr->ctlr_handle, TW_CL_FALSE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_ERROR,
0x1300, 0x3, TW_CL_SEVERITY_INFO_STRING,
"Controller details:",
"Model %.16s, %d ports, Firmware %.16s, BIOS %.16s",
error[2]?(TW_INT8 *)TW_CL_NULL:ctlr_model,
num_ports,
error[0]?(TW_INT8 *)TW_CL_NULL:fw_ver,
error[1]?(TW_INT8 *)TW_CL_NULL:bios_ver);
}
/*
* Function name: tw_cli_check_ctlr_state
* Description: Makes sure that the fw status register reports a
* proper status.
*
* Input: ctlr -- ptr to CL internal ctlr context
* status_reg-- value in the status register
* Output: None
* Return value: 0 -- no errors
* non-zero-- errors
*/
TW_INT32
tw_cli_check_ctlr_state(struct tw_cli_ctlr_context *ctlr, TW_UINT32 status_reg)
{
struct tw_cl_ctlr_handle *ctlr_handle = ctlr->ctlr_handle;
TW_INT32 error = TW_OSL_ESUCCESS;
tw_cli_dbg_printf(8, ctlr->ctlr_handle, tw_osl_cur_func(), "entered");
/* Check if the 'micro-controller ready' bit is not set. */
if ((status_reg & TWA_STATUS_EXPECTED_BITS) !=
TWA_STATUS_EXPECTED_BITS) {
TW_INT8 desc[200];
tw_osl_memzero(desc, 200);
if ((status_reg & TWA_STATUS_MICROCONTROLLER_READY) ||
(!(ctlr->state &
TW_CLI_CTLR_STATE_RESET_PHASE1_IN_PROGRESS))) {
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1301, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"Missing expected status bit(s)",
"status reg = 0x%x; Missing bits: %s",
status_reg,
tw_cli_describe_bits (~status_reg &
TWA_STATUS_EXPECTED_BITS, desc));
error = TW_OSL_EGENFAILURE;
}
}
/* Check if any error bits are set. */
if ((status_reg & TWA_STATUS_UNEXPECTED_BITS) != 0) {
TW_INT8 desc[200];
tw_osl_memzero(desc, 200);
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1302, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"Unexpected status bit(s)",
"status reg = 0x%x Unexpected bits: %s",
status_reg & TWA_STATUS_UNEXPECTED_BITS,
tw_cli_describe_bits(status_reg &
TWA_STATUS_UNEXPECTED_BITS, desc));
if (status_reg & TWA_STATUS_PCI_PARITY_ERROR_INTERRUPT) {
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1303, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"PCI parity error: clearing... "
"Re-seat/move/replace card",
"status reg = 0x%x %s",
status_reg,
tw_cli_describe_bits(status_reg, desc));
TW_CLI_WRITE_CONTROL_REGISTER(ctlr->ctlr_handle,
TWA_CONTROL_CLEAR_PARITY_ERROR);
#ifdef TW_OSL_PCI_CONFIG_ACCESSIBLE
tw_osl_write_pci_config(ctlr->ctlr_handle,
TW_CLI_PCI_CONFIG_STATUS_OFFSET,
TWA_PCI_CONFIG_CLEAR_PARITY_ERROR, 2);
#endif /* TW_OSL_PCI_CONFIG_ACCESSIBLE */
}
if (status_reg & TWA_STATUS_PCI_ABORT_INTERRUPT) {
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1304, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"PCI abort: clearing... ",
"status reg = 0x%x %s",
status_reg,
tw_cli_describe_bits(status_reg, desc));
TW_CLI_WRITE_CONTROL_REGISTER(ctlr->ctlr_handle,
TWA_CONTROL_CLEAR_PCI_ABORT);
#ifdef TW_OSL_PCI_CONFIG_ACCESSIBLE
tw_osl_write_pci_config(ctlr->ctlr_handle,
TW_CLI_PCI_CONFIG_STATUS_OFFSET,
TWA_PCI_CONFIG_CLEAR_PCI_ABORT, 2);
#endif /* TW_OSL_PCI_CONFIG_ACCESSIBLE */
}
if (status_reg & TWA_STATUS_QUEUE_ERROR_INTERRUPT) {
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1305, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"Controller queue error: clearing... ",
"status reg = 0x%x %s",
status_reg,
tw_cli_describe_bits(status_reg, desc));
TW_CLI_WRITE_CONTROL_REGISTER(ctlr->ctlr_handle,
TWA_CONTROL_CLEAR_QUEUE_ERROR);
}
if (status_reg & TWA_STATUS_MICROCONTROLLER_ERROR) {
tw_cl_create_event(ctlr_handle, TW_CL_TRUE,
TW_CL_MESSAGE_SOURCE_COMMON_LAYER_EVENT,
0x1307, 0x1, TW_CL_SEVERITY_ERROR_STRING,
"Micro-controller error! ",
"status reg = 0x%x %s",
status_reg,
tw_cli_describe_bits(status_reg, desc));
error = TW_OSL_EGENFAILURE;
}
}
return(error);
}
/*
* Function name: tw_cli_describe_bits
* Description: Given the value of the status register, returns a
* string describing the meaning of each set bit.
*
* Input: reg -- status register value
* Output: Pointer to a string describing each set bit
* Return value: Pointer to the string describing each set bit
*/
TW_INT8 *
tw_cli_describe_bits(TW_UINT32 reg, TW_INT8 *str)
{
tw_osl_strcpy(str, "[");
if (reg & TWA_STATUS_COMMAND_QUEUE_EMPTY)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "CMD_Q_EMPTY,");
if (reg & TWA_STATUS_MICROCONTROLLER_READY)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "MC_RDY,");
if (reg & TWA_STATUS_RESPONSE_QUEUE_EMPTY)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "RESP_Q_EMPTY,");
if (reg & TWA_STATUS_COMMAND_QUEUE_FULL)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "CMD_Q_FULL,");
if (reg & TWA_STATUS_RESPONSE_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "RESP_INTR,");
if (reg & TWA_STATUS_COMMAND_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "CMD_INTR,");
if (reg & TWA_STATUS_ATTENTION_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "ATTN_INTR,");
if (reg & TWA_STATUS_HOST_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "HOST_INTR,");
if (reg & TWA_STATUS_PCI_ABORT_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "PCI_ABRT,");
if (reg & TWA_STATUS_MICROCONTROLLER_ERROR)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "MC_ERR,");
if (reg & TWA_STATUS_QUEUE_ERROR_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "Q_ERR,");
if (reg & TWA_STATUS_PCI_PARITY_ERROR_INTERRUPT)
tw_osl_strcpy(&str[tw_osl_strlen(str)], "PCI_PERR");
tw_osl_strcpy(&str[tw_osl_strlen(str)], "]");
return(str);
}
#ifdef TW_OSL_DEBUG
/*
* Function name: tw_cl_print_ctlr_stats
* Description: Prints the current status of the controller.
*
* Input: ctlr_handle-- controller handle
* Output: None
* Return value: None
*/
TW_VOID
tw_cl_print_ctlr_stats(struct tw_cl_ctlr_handle *ctlr_handle)
{
struct tw_cli_ctlr_context *ctlr =
(struct tw_cli_ctlr_context *)(ctlr_handle->cl_ctlr_ctxt);
TW_UINT32 status_reg;
TW_INT8 desc[200];
tw_cli_dbg_printf(7, ctlr->ctlr_handle, "", "entered");
/* Print current controller details. */
tw_cli_dbg_printf(0, ctlr_handle, "", "cl_ctlr_ctxt = %p", ctlr);
tw_osl_memzero(desc, 200);
status_reg = TW_CLI_READ_STATUS_REGISTER(ctlr_handle);
tw_cli_dbg_printf(0, ctlr_handle, "", "status reg = 0x%x %s",
status_reg, tw_cli_describe_bits(status_reg, desc));
tw_cli_dbg_printf(0, ctlr_handle, "", "CLq type current max");
tw_cli_dbg_printf(0, ctlr_handle, "", "free %04d %04d",
ctlr->q_stats[TW_CLI_FREE_Q].cur_len,
ctlr->q_stats[TW_CLI_FREE_Q].max_len);
tw_cli_dbg_printf(0, ctlr_handle, "", "busy %04d %04d",
ctlr->q_stats[TW_CLI_BUSY_Q].cur_len,
ctlr->q_stats[TW_CLI_BUSY_Q].max_len);
tw_cli_dbg_printf(0, ctlr_handle, "", "pending %04d %04d",
ctlr->q_stats[TW_CLI_PENDING_Q].cur_len,
ctlr->q_stats[TW_CLI_PENDING_Q].max_len);
tw_cli_dbg_printf(0, ctlr_handle, "", "complete %04d %04d",
ctlr->q_stats[TW_CLI_COMPLETE_Q].cur_len,
ctlr->q_stats[TW_CLI_COMPLETE_Q].max_len);
tw_cli_dbg_printf(0, ctlr_handle, "", "AEN queue head %d tail %d",
ctlr->aen_head, ctlr->aen_tail);
}
/*
* Function name: tw_cl_reset_stats
* Description: Resets CL maintained statistics for the controller.
*
* Input: ctlr_handle-- controller handle
* Output: None
* Return value: None
*/
TW_VOID
tw_cl_reset_stats(struct tw_cl_ctlr_handle *ctlr_handle)
{
struct tw_cli_ctlr_context *ctlr =
(struct tw_cli_ctlr_context *)(ctlr_handle->cl_ctlr_ctxt);
tw_cli_dbg_printf(7, ctlr_handle, tw_osl_cur_func(), "entered");
ctlr->q_stats[TW_CLI_FREE_Q].max_len = 0;
ctlr->q_stats[TW_CLI_BUSY_Q].max_len = 0;
ctlr->q_stats[TW_CLI_PENDING_Q].max_len = 0;
ctlr->q_stats[TW_CLI_COMPLETE_Q].max_len = 0;
}
/*
* Function name: tw_cli_print_req_info
* Description: Prints CL internal details of a given request.
*
* Input: req -- ptr to CL internal request context
* Output: None
* Return value: None
*/
TW_VOID
tw_cl_print_req_info(struct tw_cl_req_handle *req_handle)
{
struct tw_cli_req_context *req = req_handle->cl_req_ctxt;
struct tw_cli_ctlr_context *ctlr = req->ctlr;
struct tw_cl_ctlr_handle *ctlr_handle = ctlr->ctlr_handle;
struct tw_cl_command_packet *cmd_pkt = req->cmd_pkt;
struct tw_cl_command_9k *cmd9k;
union tw_cl_command_7k *cmd7k;
TW_UINT8 *cdb;
TW_VOID *sgl;
TW_UINT32 sgl_entries;
TW_UINT32 i;
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"CL details for request:");
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"req_handle = %p, ctlr = %p,\n"
"cmd_pkt = %p, cmd_pkt_phys = 0x%llx,\n"
"data = %p, length = 0x%x, data_phys = 0x%llx,\n"
"state = 0x%x, flags = 0x%x, error = 0x%x,\n"
"orig_req = %p, callback = %p, req_id = 0x%x,\n"
"next_req = %p, prev_req = %p",
req_handle, ctlr,
cmd_pkt, req->cmd_pkt_phys,
req->data, req->length, req->data_phys,
req->state, req->flags, req->error_code,
req->orig_req, req->tw_cli_callback, req->request_id,
req->link.next, req->link.prev);
if (req->flags & TW_CLI_REQ_FLAGS_9K) {
cmd9k = &(cmd_pkt->command.cmd_pkt_9k);
sgl = cmd9k->sg_list;
sgl_entries = TW_CL_SWAP16(
GET_SGL_ENTRIES(cmd9k->lun_h4__sgl_entries));
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"9K cmd: opcode = 0x%x, unit = 0x%x, req_id = 0x%x,\n"
"status = 0x%x, sgl_offset = 0x%x, sgl_entries = 0x%x",
GET_OPCODE(cmd9k->res__opcode),
cmd9k->unit,
TW_CL_SWAP16(GET_REQ_ID(cmd9k->lun_l4__req_id)),
cmd9k->status,
cmd9k->sgl_offset,
sgl_entries);
cdb = (TW_UINT8 *)(cmd9k->cdb);
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"CDB: %x %x %x %x %x %x %x %x"
"%x %x %x %x %x %x %x %x",
cdb[0], cdb[1], cdb[2], cdb[3],
cdb[4], cdb[5], cdb[6], cdb[7],
cdb[8], cdb[9], cdb[10], cdb[11],
cdb[12], cdb[13], cdb[14], cdb[15]);
} else {
cmd7k = &(cmd_pkt->command.cmd_pkt_7k);
sgl = cmd7k->param.sgl;
sgl_entries = (cmd7k->generic.size -
GET_SGL_OFF(cmd7k->generic.sgl_off__opcode)) /
((ctlr->flags & TW_CL_64BIT_ADDRESSES) ? 3 : 2);
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"7K cmd: opcode = 0x%x, sgl_offset = 0x%x,\n"
"size = 0x%x, req_id = 0x%x, unit = 0x%x,\n"
"status = 0x%x, flags = 0x%x, count = 0x%x",
GET_OPCODE(cmd7k->generic.sgl_off__opcode),
GET_SGL_OFF(cmd7k->generic.sgl_off__opcode),
cmd7k->generic.size,
TW_CL_SWAP16(cmd7k->generic.request_id),
GET_UNIT(cmd7k->generic.host_id__unit),
cmd7k->generic.status,
cmd7k->generic.flags,
TW_CL_SWAP16(cmd7k->generic.count));
}
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(), "SG entries:");
if (ctlr->flags & TW_CL_64BIT_ADDRESSES) {
struct tw_cl_sg_desc64 *sgl64 = (struct tw_cl_sg_desc64 *)sgl;
for (i = 0; i < sgl_entries; i++) {
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"0x%llx 0x%x",
sgl64[i].address, sgl64[i].length);
}
} else {
struct tw_cl_sg_desc32 *sgl32 = (struct tw_cl_sg_desc32 *)sgl;
for (i = 0; i < sgl_entries; i++) {
tw_cli_dbg_printf(0, ctlr_handle, tw_osl_cur_func(),
"0x%x 0x%x",
sgl32[i].address, sgl32[i].length);
}
}
}
#endif /* TW_OSL_DEBUG */