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/* Copyright 2013-2014 IBM Corp.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
* implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <skiboot.h>
#include <fsp.h>
#include <lock.h>
#include <timebase.h>
#include <time.h>
#include <time-utils.h>
#include <opal-api.h>
#include <opal-msg.h>
#include <errorlog.h>
#include <device.h>
/*
* Note on how those operate:
*
* Because the RTC calls can be pretty slow, these functions will shoot
* an asynchronous request to the FSP (if none is already pending)
*
* The requests will return OPAL_BUSY_EVENT as long as the event has
* not been completed.
*
* WARNING: An attempt at doing an RTC write while one is already pending
* will simply ignore the new arguments and continue returning
* OPAL_BUSY_EVENT. This is to be compatible with existing Linux code.
*
* Completion of the request will result in an event OPAL_EVENT_RTC
* being signaled, which will remain raised until a corresponding call
* to opal_rtc_read() or opal_rtc_write() finally returns OPAL_SUCCESS,
* at which point the operation is complete and the event cleared.
*
* If we end up taking longer than rtc_read_timeout_ms millieconds waiting
* for the response from a read request, we simply return a cached value (plus
* an offset calculated from the timebase. When the read request finally
* returns, we update our cache value accordingly.
*
* There is two separate set of state for reads and writes. If both are
* attempted at the same time, the event bit will remain set as long as either
* of the two has a pending event to signal.
*/
#include <rtc.h>
enum {
RTC_TOD_VALID,
RTC_TOD_INVALID,
RTC_TOD_PERMANENT_ERROR,
} rtc_tod_state = RTC_TOD_INVALID;
bool rtc_tod_cache_dirty = false;
static struct lock rtc_lock;
static struct fsp_msg *rtc_read_msg;
static struct fsp_msg *rtc_write_msg;
/* TODO We'd probably want to export and use this variable declared in fsp.c,
* instead of each component individually maintaining the state.. may be for
* later optimization
*/
static bool fsp_in_reset = false;
struct opal_tpo_data {
uint64_t tpo_async_token;
uint32_t *year_month_day;
uint32_t *hour_min;
};
/* Timebase value when we last initiated a RTC read request */
static unsigned long read_req_tb;
/* If a RTC read takes longer than this, we return a value generated
* from the cache + timebase */
static const int rtc_read_timeout_ms = 1500;
DEFINE_LOG_ENTRY(OPAL_RC_RTC_TOD, OPAL_PLATFORM_ERR_EVT, OPAL_RTC,
OPAL_PLATFORM_FIRMWARE, OPAL_INFO,
OPAL_NA, NULL);
DEFINE_LOG_ENTRY(OPAL_RC_RTC_READ, OPAL_PLATFORM_ERR_EVT, OPAL_RTC,
OPAL_PLATFORM_FIRMWARE, OPAL_INFO,
OPAL_NA, NULL);
static void fsp_tpo_req_complete(struct fsp_msg *read_resp)
{
struct opal_tpo_data *attr = read_resp->user_data;
int val;
int rc;
val = (read_resp->resp->word1 >> 8) & 0xff;
switch (val) {
case FSP_STATUS_TOD_RESET:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TPO in invalid state\n");
rc = OPAL_INTERNAL_ERROR;
break;
case FSP_STATUS_TOD_PERMANENT_ERROR:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TPO in permanent error state\n");
rc = OPAL_INTERNAL_ERROR;
break;
case FSP_STATUS_INVALID_DATA:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TPO in permanent error state\n");
rc = OPAL_PARAMETER;
break;
case FSP_STATUS_SUCCESS:
/* Save the read TPO value in our cache */
if (attr->year_month_day)
*(attr->year_month_day) =
read_resp->resp->data.words[0];
if (attr->hour_min)
*(attr->hour_min) = read_resp->resp->data.words[1];
rc = OPAL_SUCCESS;
break;
default:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"TPO read failed: %d\n", val);
rc = OPAL_INTERNAL_ERROR;
break;
}
opal_queue_msg(OPAL_MSG_ASYNC_COMP, NULL, NULL,
attr->tpo_async_token, rc);
free(attr);
fsp_freemsg(read_resp);
}
static void fsp_rtc_process_read(struct fsp_msg *read_resp)
{
int val = (read_resp->word1 >> 8) & 0xff;
struct tm tm;
switch (val) {
case FSP_STATUS_TOD_RESET:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TOD in invalid state\n");
rtc_tod_state = RTC_TOD_INVALID;
break;
case FSP_STATUS_TOD_PERMANENT_ERROR:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TOD in permanent error state\n");
rtc_tod_state = RTC_TOD_PERMANENT_ERROR;
break;
case FSP_STATUS_SUCCESS:
/* Save the read RTC value in our cache */
rtc_tod_state = RTC_TOD_VALID;
datetime_to_tm(read_resp->data.words[0],
(u64) read_resp->data.words[1] << 32, &tm);
rtc_cache_update(&tm);
prlog(PR_TRACE, "FSP-RTC Got time: %d-%d-%d %d:%d:%d\n",
tm.tm_year, tm.tm_mon, tm.tm_mday,
tm.tm_hour, tm.tm_min, tm.tm_sec);
break;
default:
log_simple_error(&e_info(OPAL_RC_RTC_TOD),
"RTC TOD read failed: %d\n", val);
rtc_tod_state = RTC_TOD_INVALID;
}
}
static void opal_rtc_eval_events(void)
{
bool pending = false;
if (rtc_read_msg && !fsp_msg_busy(rtc_read_msg))
pending = true;
if (rtc_write_msg && !fsp_msg_busy(rtc_write_msg))
pending = true;
opal_update_pending_evt(OPAL_EVENT_RTC, pending ? OPAL_EVENT_RTC : 0);
}
static void fsp_rtc_req_complete(struct fsp_msg *msg)
{
lock(&rtc_lock);
prlog(PR_TRACE, "RTC completion %p\n", msg);
if (msg == rtc_read_msg)
fsp_rtc_process_read(msg->resp);
opal_rtc_eval_events();
unlock(&rtc_lock);
}
static int64_t fsp_rtc_send_read_request(void)
{
struct fsp_msg *msg;
int rc;
msg = fsp_mkmsg(FSP_CMD_READ_TOD, 0);
if (!msg) {
log_simple_error(&e_info(OPAL_RC_RTC_READ),
"RTC: failed to allocate read message\n");
return OPAL_INTERNAL_ERROR;
}
rc = fsp_queue_msg(msg, fsp_rtc_req_complete);
if (rc) {
fsp_freemsg(msg);
log_simple_error(&e_info(OPAL_RC_RTC_READ),
"RTC: failed to queue read message: %d\n", rc);
return OPAL_INTERNAL_ERROR;
}
read_req_tb = mftb();
rtc_read_msg = msg;
return OPAL_BUSY_EVENT;
}
static int64_t fsp_opal_rtc_read(uint32_t *year_month_day,
uint64_t *hour_minute_second_millisecond)
{
struct fsp_msg *msg;
int64_t rc;
if (!year_month_day || !hour_minute_second_millisecond)
return OPAL_PARAMETER;
lock(&rtc_lock);
/* During R/R of FSP, read cached TOD */
if (fsp_in_reset) {
rtc_cache_get_datetime(year_month_day,
hour_minute_second_millisecond);
rc = OPAL_SUCCESS;
goto out;
}
msg = rtc_read_msg;
if (rtc_tod_state == RTC_TOD_PERMANENT_ERROR) {
if (msg && !fsp_msg_busy(msg))
fsp_freemsg(msg);
rc = OPAL_HARDWARE;
goto out;
}
/* If we don't have a read pending already, fire off a request and
* return */
if (!msg) {
prlog(PR_TRACE, "Sending new RTC read request\n");
rc = fsp_rtc_send_read_request();
/* If our pending read is done, clear events and return the time
* from the cache */
} else if (!fsp_msg_busy(msg)) {
prlog(PR_TRACE, "RTC read complete, state %d\n", rtc_tod_state);
rtc_read_msg = NULL;
opal_rtc_eval_events();
fsp_freemsg(msg);
if (rtc_tod_state == RTC_TOD_VALID) {
rtc_cache_get_datetime(year_month_day,
hour_minute_second_millisecond);
prlog(PR_TRACE,"FSP-RTC Cached datetime: %x %llx\n",
*year_month_day,
*hour_minute_second_millisecond);
rc = OPAL_SUCCESS;
} else
rc = OPAL_INTERNAL_ERROR;
/* Timeout: return our cached value (updated from tb), but leave the
* read request pending so it will update the cache later */
} else if (mftb() > read_req_tb + msecs_to_tb(rtc_read_timeout_ms)) {
prlog(PR_TRACE, "RTC read timed out\n");
rtc_cache_get_datetime(year_month_day,
hour_minute_second_millisecond);
rc = OPAL_SUCCESS;
/* Otherwise, we're still waiting on the read to complete */
} else {
rc = OPAL_BUSY_EVENT;
}
out:
unlock(&rtc_lock);
return rc;
}
static int64_t fsp_opal_rtc_write(uint32_t year_month_day,
uint64_t hour_minute_second_millisecond)
{
struct fsp_msg *msg;
uint32_t w0, w1, w2;
int64_t rc;
struct tm tm;
lock(&rtc_lock);
if (rtc_tod_state == RTC_TOD_PERMANENT_ERROR) {
rc = OPAL_HARDWARE;
msg = NULL;
goto bail;
}
/* Do we have a request already ? */
msg = rtc_write_msg;
if (msg) {
/* If it's still in progress, return */
if (fsp_msg_busy(msg)) {
/* Don't free the message */
msg = NULL;
rc = OPAL_BUSY_EVENT;
goto bail;
}
prlog(PR_TRACE, "Completed write request @%p, state=%d\n",
msg, msg->state);
/* It's complete, clear events */
rtc_write_msg = NULL;
opal_rtc_eval_events();
/* Check error state */
if (msg->state != fsp_msg_done) {
prlog(PR_TRACE, " -> request not in done state ->"
" error !\n");
rc = OPAL_INTERNAL_ERROR;
goto bail;
}
rc = OPAL_SUCCESS;
goto bail;
}
prlog(PR_TRACE, "Sending new write request...\n");
/* Create a request and send it. Just like for read, we ignore
* the "millisecond" field which is probably supposed to be
* microseconds and which Linux ignores as well anyway
*/
w0 = year_month_day;
w1 = (hour_minute_second_millisecond >> 32) & 0xffffff00;
w2 = 0;
rtc_write_msg = fsp_mkmsg(FSP_CMD_WRITE_TOD, 3, w0, w1, w2);
if (!rtc_write_msg) {
prlog(PR_TRACE, " -> allocation failed !\n");
rc = OPAL_INTERNAL_ERROR;
goto bail;
}
prlog(PR_TRACE, " -> req at %p\n", rtc_write_msg);
if (fsp_in_reset) {
datetime_to_tm(rtc_write_msg->data.words[0],
(u64) rtc_write_msg->data.words[1] << 32, &tm);
rtc_cache_update(&tm);
rtc_tod_cache_dirty = true;
fsp_freemsg(rtc_write_msg);
rtc_write_msg = NULL;
rc = OPAL_SUCCESS;
goto bail;
} else if (fsp_queue_msg(rtc_write_msg, fsp_rtc_req_complete)) {
prlog(PR_TRACE, " -> queueing failed !\n");
rc = OPAL_INTERNAL_ERROR;
fsp_freemsg(rtc_write_msg);
rtc_write_msg = NULL;
goto bail;
}
rc = OPAL_BUSY_EVENT;
bail:
unlock(&rtc_lock);
if (msg)
fsp_freemsg(msg);
return rc;
}
/* Set timed power on values to fsp */
static int64_t fsp_opal_tpo_write(uint64_t async_token, uint32_t y_m_d,
uint32_t hr_min)
{
static struct opal_tpo_data *attr;
struct fsp_msg *msg;
if (!fsp_present())
return OPAL_HARDWARE;
attr = zalloc(sizeof(struct opal_tpo_data));
if (!attr)
return OPAL_NO_MEM;
/* Create a request and send it.*/
attr->tpo_async_token = async_token;
prlog(PR_TRACE, "Sending TPO write request...\n");
msg = fsp_mkmsg(FSP_CMD_TPO_WRITE, 2, y_m_d, hr_min);
if (!msg) {
prerror("TPO: Failed to create message for WRITE to FSP\n");
free(attr);
return OPAL_INTERNAL_ERROR;
}
msg->user_data = attr;
if (fsp_queue_msg(msg, fsp_tpo_req_complete)) {
free(attr);
fsp_freemsg(msg);
return OPAL_INTERNAL_ERROR;
}
return OPAL_ASYNC_COMPLETION;
}
/* Read Timed power on (TPO) from FSP */
static int64_t fsp_opal_tpo_read(uint64_t async_token, uint32_t *y_m_d,
uint32_t *hr_min)
{
static struct opal_tpo_data *attr;
struct fsp_msg *msg;
int64_t rc;
if (!fsp_present())
return OPAL_HARDWARE;
if (!y_m_d || !hr_min)
return OPAL_PARAMETER;
attr = zalloc(sizeof(*attr));
if (!attr)
return OPAL_NO_MEM;
/* Send read requet to FSP */
attr->tpo_async_token = async_token;
attr->year_month_day = y_m_d;
attr->hour_min = hr_min;
prlog(PR_TRACE, "Sending new TPO read request\n");
msg = fsp_mkmsg(FSP_CMD_TPO_READ, 0);
if (!msg) {
log_simple_error(&e_info(OPAL_RC_RTC_READ),
"TPO: failed to allocate read message\n");
free(attr);
return OPAL_INTERNAL_ERROR;
}
msg->user_data = attr;
rc = fsp_queue_msg(msg, fsp_tpo_req_complete);
if (rc) {
free(attr);
fsp_freemsg(msg);
log_simple_error(&e_info(OPAL_RC_RTC_READ),
"TPO: failed to queue read message: %lld\n", rc);
return OPAL_INTERNAL_ERROR;
}
return OPAL_ASYNC_COMPLETION;
}
static void rtc_flush_cached_tod(void)
{
struct fsp_msg *msg;
uint64_t h_m_s_m;
uint32_t y_m_d;
if (rtc_cache_get_datetime(&y_m_d, &h_m_s_m))
return;
msg = fsp_mkmsg(FSP_CMD_WRITE_TOD, 3, y_m_d,
(h_m_s_m >> 32) & 0xffffff00, 0);
if (!msg) {
prerror("TPO: %s : Failed to allocate write TOD message\n",
__func__);
return;
}
if (fsp_queue_msg(msg, fsp_freemsg)) {
fsp_freemsg(msg);
prerror("TPO: %s : Failed to queue WRITE_TOD command\n",
__func__);
return;
}
}
static bool fsp_rtc_msg_rr(u32 cmd_sub_mod, struct fsp_msg *msg)
{
int rc = false;
assert(msg == NULL);
switch (cmd_sub_mod) {
case FSP_RESET_START:
lock(&rtc_lock);
fsp_in_reset = true;
unlock(&rtc_lock);
rc = true;
break;
case FSP_RELOAD_COMPLETE:
lock(&rtc_lock);
fsp_in_reset = false;
if (rtc_tod_cache_dirty) {
rtc_flush_cached_tod();
rtc_tod_cache_dirty = false;
}
unlock(&rtc_lock);
rc = true;
break;
}
return rc;
}
static struct fsp_client fsp_rtc_client_rr = {
.message = fsp_rtc_msg_rr,
};
void fsp_rtc_init(void)
{
struct fsp_msg msg, resp;
struct dt_node *np;
int rc;
if (!fsp_present()) {
rtc_tod_state = RTC_TOD_PERMANENT_ERROR;
return;
}
opal_register(OPAL_RTC_READ, fsp_opal_rtc_read, 2);
opal_register(OPAL_RTC_WRITE, fsp_opal_rtc_write, 2);
opal_register(OPAL_WRITE_TPO, fsp_opal_tpo_write, 3);
opal_register(OPAL_READ_TPO, fsp_opal_tpo_read, 3);
np = dt_new(opal_node, "rtc");
dt_add_property_strings(np, "compatible", "ibm,opal-rtc");
dt_add_property(np, "has-tpo", NULL, 0);
/* Register for the reset/reload event */
fsp_register_client(&fsp_rtc_client_rr, FSP_MCLASS_RR_EVENT);
msg.resp = &resp;
fsp_fillmsg(&msg, FSP_CMD_READ_TOD, 0);
prlog(PR_TRACE, "Getting initial RTC TOD\n");
lock(&rtc_lock);
rc = fsp_sync_msg(&msg, false);
if (rc >= 0) {
fsp_rtc_process_read(&resp);
} else {
rtc_tod_state = RTC_TOD_PERMANENT_ERROR;
prlog(PR_ERR, "Failed to get initial FSP-RTC TOD %d\n",rc);
}
unlock(&rtc_lock);
}
|