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|
/*
* Copyright (c) 2016-2018, NVIDIA CORPORATION. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
#include <nvgpu/bitops.h>
#include <nvgpu/lock.h>
#include <nvgpu/kmem.h>
#include <nvgpu/atomic.h>
#include <nvgpu/bug.h>
#include <nvgpu/kref.h>
#include <nvgpu/log.h>
#include <nvgpu/barrier.h>
#include <nvgpu/cond.h>
#include <nvgpu/list.h>
#include <nvgpu/clk_arb.h>
#include <nvgpu/timers.h>
#include <nvgpu/gk20a.h>
#include "clk/clk.h"
#include "pstate/pstate.h"
#include "lpwr/lpwr.h"
#include "volt/volt.h"
int nvgpu_clk_notification_queue_alloc(struct gk20a *g,
struct nvgpu_clk_notification_queue *queue,
size_t events_number) {
queue->notifications = nvgpu_kcalloc(g, events_number,
sizeof(struct nvgpu_clk_notification));
if (!queue->notifications)
return -ENOMEM;
queue->size = events_number;
nvgpu_atomic_set(&queue->head, 0);
nvgpu_atomic_set(&queue->tail, 0);
return 0;
}
void nvgpu_clk_notification_queue_free(struct gk20a *g,
struct nvgpu_clk_notification_queue *queue) {
if (queue->size > 0) {
nvgpu_kfree(g, queue->notifications);
queue->size = 0;
nvgpu_atomic_set(&queue->head, 0);
nvgpu_atomic_set(&queue->tail, 0);
}
}
static void nvgpu_clk_arb_queue_notification(struct gk20a *g,
struct nvgpu_clk_notification_queue *queue,
u32 alarm_mask) {
u32 queue_index;
u64 timestamp;
queue_index = (nvgpu_atomic_inc_return(&queue->tail)) % queue->size;
/* get current timestamp */
timestamp = (u64) nvgpu_hr_timestamp();
queue->notifications[queue_index].timestamp = timestamp;
queue->notifications[queue_index].notification = alarm_mask;
}
void nvgpu_clk_arb_set_global_alarm(struct gk20a *g, u32 alarm)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
u64 current_mask;
u32 refcnt;
u32 alarm_mask;
u64 new_mask;
do {
current_mask = nvgpu_atomic64_read(&arb->alarm_mask);
/* atomic operations are strong so they do not need masks */
refcnt = ((u32) (current_mask >> 32)) + 1;
alarm_mask = (u32) (current_mask & ~0) | alarm;
new_mask = ((u64) refcnt << 32) | alarm_mask;
} while (unlikely(current_mask !=
(u64)nvgpu_atomic64_cmpxchg(&arb->alarm_mask,
current_mask, new_mask)));
nvgpu_clk_arb_queue_notification(g, &arb->notification_queue, alarm);
}
int nvgpu_clk_arb_update_vf_table(struct nvgpu_clk_arb *arb)
{
struct gk20a *g = arb->g;
struct nvgpu_clk_vf_table *table;
u32 i, j;
int status = -EINVAL;
u32 gpc2clk_voltuv = 0, mclk_voltuv = 0;
u32 gpc2clk_voltuv_sram = 0, mclk_voltuv_sram = 0;
u16 clk_cur;
u32 num_points;
struct clk_set_info *p5_info, *p0_info;
table = NV_ACCESS_ONCE(arb->current_vf_table);
/* make flag visible when all data has resolved in the tables */
nvgpu_smp_rmb();
table = (table == &arb->vf_table_pool[0]) ? &arb->vf_table_pool[1] :
&arb->vf_table_pool[0];
/* Get allowed memory ranges */
if (g->ops.clk_arb.get_arbiter_clk_range(g, CTRL_CLK_DOMAIN_GPC2CLK,
&arb->gpc2clk_min,
&arb->gpc2clk_max) < 0) {
nvgpu_err(g, "failed to fetch GPC2CLK range");
goto exit_vf_table;
}
if (g->ops.clk_arb.get_arbiter_clk_range(g, CTRL_CLK_DOMAIN_MCLK,
&arb->mclk_min,
&arb->mclk_max) < 0) {
nvgpu_err(g, "failed to fetch MCLK range");
goto exit_vf_table;
}
table->gpc2clk_num_points = MAX_F_POINTS;
table->mclk_num_points = MAX_F_POINTS;
if (g->ops.clk.clk_domain_get_f_points(arb->g, CTRL_CLK_DOMAIN_GPC2CLK,
&table->gpc2clk_num_points, arb->gpc2clk_f_points)) {
nvgpu_err(g, "failed to fetch GPC2CLK frequency points");
goto exit_vf_table;
}
if (g->ops.clk.clk_domain_get_f_points(arb->g, CTRL_CLK_DOMAIN_MCLK,
&table->mclk_num_points, arb->mclk_f_points)) {
nvgpu_err(g, "failed to fetch MCLK frequency points");
goto exit_vf_table;
}
if (!table->mclk_num_points || !table->gpc2clk_num_points) {
nvgpu_err(g, "empty queries to f points mclk %d gpc2clk %d",
table->mclk_num_points, table->gpc2clk_num_points);
status = -EINVAL;
goto exit_vf_table;
}
memset(table->mclk_points, 0,
table->mclk_num_points*sizeof(struct nvgpu_clk_vf_point));
memset(table->gpc2clk_points, 0,
table->gpc2clk_num_points*sizeof(struct nvgpu_clk_vf_point));
p5_info = pstate_get_clk_set_info(g,
CTRL_PERF_PSTATE_P5, clkwhich_mclk);
if (!p5_info) {
nvgpu_err(g, "failed to get MCLK P5 info");
goto exit_vf_table;
}
p0_info = pstate_get_clk_set_info(g,
CTRL_PERF_PSTATE_P0, clkwhich_mclk);
if (!p0_info) {
nvgpu_err(g, "failed to get MCLK P0 info");
goto exit_vf_table;
}
for (i = 0, j = 0, num_points = 0, clk_cur = 0;
i < table->mclk_num_points; i++) {
if ((arb->mclk_f_points[i] >= arb->mclk_min) &&
(arb->mclk_f_points[i] <= arb->mclk_max) &&
(arb->mclk_f_points[i] != clk_cur)) {
table->mclk_points[j].mem_mhz = arb->mclk_f_points[i];
mclk_voltuv = mclk_voltuv_sram = 0;
status = clk_domain_get_f_or_v(g, CTRL_CLK_DOMAIN_MCLK,
&table->mclk_points[j].mem_mhz, &mclk_voltuv,
CTRL_VOLT_DOMAIN_LOGIC);
if (status < 0) {
nvgpu_err(g,
"failed to get MCLK LOGIC voltage");
goto exit_vf_table;
}
status = clk_domain_get_f_or_v(g, CTRL_CLK_DOMAIN_MCLK,
&table->mclk_points[j].mem_mhz,
&mclk_voltuv_sram,
CTRL_VOLT_DOMAIN_SRAM);
if (status < 0) {
nvgpu_err(g, "failed to get MCLK SRAM voltage");
goto exit_vf_table;
}
table->mclk_points[j].uvolt = mclk_voltuv;
table->mclk_points[j].uvolt_sram = mclk_voltuv_sram;
clk_cur = table->mclk_points[j].mem_mhz;
if ((clk_cur >= p5_info->min_mhz) &&
(clk_cur <= p5_info->max_mhz))
VF_POINT_SET_PSTATE_SUPPORTED(
&table->mclk_points[j],
CTRL_PERF_PSTATE_P5);
if ((clk_cur >= p0_info->min_mhz) &&
(clk_cur <= p0_info->max_mhz))
VF_POINT_SET_PSTATE_SUPPORTED(
&table->mclk_points[j],
CTRL_PERF_PSTATE_P0);
j++;
num_points++;
}
}
table->mclk_num_points = num_points;
p5_info = pstate_get_clk_set_info(g,
CTRL_PERF_PSTATE_P5, clkwhich_gpc2clk);
if (!p5_info) {
status = -EINVAL;
nvgpu_err(g, "failed to get GPC2CLK P5 info");
goto exit_vf_table;
}
p0_info = pstate_get_clk_set_info(g,
CTRL_PERF_PSTATE_P0, clkwhich_gpc2clk);
if (!p0_info) {
status = -EINVAL;
nvgpu_err(g, "failed to get GPC2CLK P0 info");
goto exit_vf_table;
}
/* GPC2CLK needs to be checked in two passes. The first determines the
* relationships between GPC2CLK, SYS2CLK and XBAR2CLK, while the
* second verifies that the clocks minimum is satisfied and sets
* the voltages
*/
for (i = 0, j = 0, num_points = 0, clk_cur = 0;
i < table->gpc2clk_num_points; i++) {
struct set_fll_clk setfllclk;
if ((arb->gpc2clk_f_points[i] >= arb->gpc2clk_min) &&
(arb->gpc2clk_f_points[i] <= arb->gpc2clk_max) &&
(arb->gpc2clk_f_points[i] != clk_cur)) {
table->gpc2clk_points[j].gpc_mhz =
arb->gpc2clk_f_points[i];
setfllclk.gpc2clkmhz = arb->gpc2clk_f_points[i];
status = clk_get_fll_clks(g, &setfllclk);
if (status < 0) {
nvgpu_err(g,
"failed to get GPC2CLK slave clocks");
goto exit_vf_table;
}
table->gpc2clk_points[j].sys_mhz =
setfllclk.sys2clkmhz;
table->gpc2clk_points[j].xbar_mhz =
setfllclk.xbar2clkmhz;
clk_cur = table->gpc2clk_points[j].gpc_mhz;
if ((clk_cur >= p5_info->min_mhz) &&
(clk_cur <= p5_info->max_mhz))
VF_POINT_SET_PSTATE_SUPPORTED(
&table->gpc2clk_points[j],
CTRL_PERF_PSTATE_P5);
if ((clk_cur >= p0_info->min_mhz) &&
(clk_cur <= p0_info->max_mhz))
VF_POINT_SET_PSTATE_SUPPORTED(
&table->gpc2clk_points[j],
CTRL_PERF_PSTATE_P0);
j++;
num_points++;
}
}
table->gpc2clk_num_points = num_points;
/* Second pass */
for (i = 0, j = 0; i < table->gpc2clk_num_points; i++) {
u16 alt_gpc2clk = table->gpc2clk_points[i].gpc_mhz;
gpc2clk_voltuv = gpc2clk_voltuv_sram = 0;
/* Check sysclk */
p5_info = pstate_get_clk_set_info(g,
VF_POINT_GET_PSTATE(&table->gpc2clk_points[i]),
clkwhich_sys2clk);
if (!p5_info) {
status = -EINVAL;
nvgpu_err(g, "failed to get SYS2CLK P5 info");
goto exit_vf_table;
}
/* sys2clk below clk min, need to find correct clock */
if (table->gpc2clk_points[i].sys_mhz < p5_info->min_mhz) {
for (j = i + 1; j < table->gpc2clk_num_points; j++) {
if (table->gpc2clk_points[j].sys_mhz >=
p5_info->min_mhz) {
table->gpc2clk_points[i].sys_mhz =
p5_info->min_mhz;
alt_gpc2clk = alt_gpc2clk <
table->gpc2clk_points[j].
gpc_mhz ?
table->gpc2clk_points[j].
gpc_mhz :
alt_gpc2clk;
break;
}
}
/* no VF exists that satisfies condition */
if (j == table->gpc2clk_num_points) {
nvgpu_err(g, "NO SYS2CLK VF point possible");
status = -EINVAL;
goto exit_vf_table;
}
}
/* Check xbarclk */
p5_info = pstate_get_clk_set_info(g,
VF_POINT_GET_PSTATE(&table->gpc2clk_points[i]),
clkwhich_xbar2clk);
if (!p5_info) {
status = -EINVAL;
nvgpu_err(g, "failed to get SYS2CLK P5 info");
goto exit_vf_table;
}
/* xbar2clk below clk min, need to find correct clock */
if (table->gpc2clk_points[i].xbar_mhz < p5_info->min_mhz) {
for (j = i; j < table->gpc2clk_num_points; j++) {
if (table->gpc2clk_points[j].xbar_mhz >=
p5_info->min_mhz) {
table->gpc2clk_points[i].xbar_mhz =
p5_info->min_mhz;
alt_gpc2clk = alt_gpc2clk <
table->gpc2clk_points[j].
gpc_mhz ?
table->gpc2clk_points[j].
gpc_mhz :
alt_gpc2clk;
break;
}
}
/* no VF exists that satisfies condition */
if (j == table->gpc2clk_num_points) {
status = -EINVAL;
nvgpu_err(g, "NO XBAR2CLK VF point possible");
goto exit_vf_table;
}
}
/* Calculate voltages */
status = clk_domain_get_f_or_v(g, CTRL_CLK_DOMAIN_GPC2CLK,
&alt_gpc2clk, &gpc2clk_voltuv,
CTRL_VOLT_DOMAIN_LOGIC);
if (status < 0) {
nvgpu_err(g, "failed to get GPC2CLK LOGIC voltage");
goto exit_vf_table;
}
status = clk_domain_get_f_or_v(g, CTRL_CLK_DOMAIN_GPC2CLK,
&alt_gpc2clk,
&gpc2clk_voltuv_sram,
CTRL_VOLT_DOMAIN_SRAM);
if (status < 0) {
nvgpu_err(g, "failed to get GPC2CLK SRAM voltage");
goto exit_vf_table;
}
table->gpc2clk_points[i].uvolt = gpc2clk_voltuv;
table->gpc2clk_points[i].uvolt_sram = gpc2clk_voltuv_sram;
}
/* make table visible when all data has resolved in the tables */
nvgpu_smp_wmb();
arb->current_vf_table = table;
exit_vf_table:
if (status < 0)
nvgpu_clk_arb_set_global_alarm(g,
EVENT(ALARM_VF_TABLE_UPDATE_FAILED));
nvgpu_clk_arb_worker_enqueue(g, &arb->update_arb_work_item);
return status;
}
static void nvgpu_clk_arb_run_vf_table_cb(struct nvgpu_clk_arb *arb)
{
struct gk20a *g = arb->g;
u32 err;
/* get latest vf curve from pmu */
err = clk_vf_point_cache(g);
if (err) {
nvgpu_err(g, "failed to cache VF table");
nvgpu_clk_arb_set_global_alarm(g,
EVENT(ALARM_VF_TABLE_UPDATE_FAILED));
nvgpu_clk_arb_worker_enqueue(g, &arb->update_arb_work_item);
return;
}
nvgpu_clk_arb_update_vf_table(arb);
}
u32 nvgpu_clk_arb_notify(struct nvgpu_clk_dev *dev,
struct nvgpu_clk_arb_target *target,
u32 alarm) {
struct nvgpu_clk_session *session = dev->session;
struct nvgpu_clk_arb *arb = session->g->clk_arb;
struct nvgpu_clk_notification *notification;
u32 queue_alarm_mask = 0;
u32 enabled_mask = 0;
u32 new_alarms_reported = 0;
u32 poll_mask = 0;
u32 tail, head;
u32 queue_index;
size_t size;
int index;
enabled_mask = nvgpu_atomic_read(&dev->enabled_mask);
size = arb->notification_queue.size;
/* queue global arbiter notifications in buffer */
do {
tail = nvgpu_atomic_read(&arb->notification_queue.tail);
/* copy items to the queue */
queue_index = nvgpu_atomic_read(&dev->queue.tail);
head = dev->arb_queue_head;
head = (tail - head) < arb->notification_queue.size ?
head : tail - arb->notification_queue.size;
for (index = head; _WRAPGTEQ(tail, index); index++) {
u32 alarm_detected;
notification = &arb->notification_queue.
notifications[(index+1) % size];
alarm_detected =
NV_ACCESS_ONCE(notification->notification);
if (!(enabled_mask & alarm_detected))
continue;
queue_index++;
dev->queue.notifications[
queue_index % dev->queue.size].timestamp =
NV_ACCESS_ONCE(notification->timestamp);
dev->queue.notifications[
queue_index % dev->queue.size].notification =
alarm_detected;
queue_alarm_mask |= alarm_detected;
}
} while (unlikely(nvgpu_atomic_read(&arb->notification_queue.tail) !=
(int)tail));
nvgpu_atomic_set(&dev->queue.tail, queue_index);
/* update the last notification we processed from global queue */
dev->arb_queue_head = tail;
/* Check if current session targets are met */
if (enabled_mask & EVENT(ALARM_LOCAL_TARGET_VF_NOT_POSSIBLE)) {
if ((target->gpc2clk < session->target->gpc2clk)
|| (target->mclk < session->target->mclk)) {
poll_mask |= (NVGPU_POLLIN | NVGPU_POLLPRI);
nvgpu_clk_arb_queue_notification(arb->g, &dev->queue,
EVENT(ALARM_LOCAL_TARGET_VF_NOT_POSSIBLE));
}
}
/* Check if there is a new VF update */
if (queue_alarm_mask & EVENT(VF_UPDATE))
poll_mask |= (NVGPU_POLLIN | NVGPU_POLLRDNORM);
/* Notify sticky alarms that were not reported on previous run*/
new_alarms_reported = (queue_alarm_mask |
(alarm & ~dev->alarms_reported & queue_alarm_mask));
if (new_alarms_reported & ~LOCAL_ALARM_MASK) {
/* check that we are not re-reporting */
if (new_alarms_reported & EVENT(ALARM_GPU_LOST))
poll_mask |= NVGPU_POLLHUP;
poll_mask |= (NVGPU_POLLIN | NVGPU_POLLPRI);
/* On next run do not report global alarms that were already
* reported, but report SHUTDOWN always
*/
dev->alarms_reported = new_alarms_reported & ~LOCAL_ALARM_MASK &
~EVENT(ALARM_GPU_LOST);
}
if (poll_mask) {
nvgpu_atomic_set(&dev->poll_mask, poll_mask);
nvgpu_clk_arb_event_post_event(dev);
}
return new_alarms_reported;
}
void nvgpu_clk_arb_clear_global_alarm(struct gk20a *g, u32 alarm)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
u64 current_mask;
u32 refcnt;
u32 alarm_mask;
u64 new_mask;
do {
current_mask = nvgpu_atomic64_read(&arb->alarm_mask);
/* atomic operations are strong so they do not need masks */
refcnt = ((u32) (current_mask >> 32)) + 1;
alarm_mask = (u32) (current_mask & ~alarm);
new_mask = ((u64) refcnt << 32) | alarm_mask;
} while (unlikely(current_mask !=
(u64)nvgpu_atomic64_cmpxchg(&arb->alarm_mask,
current_mask, new_mask)));
}
/*
* Process one scheduled work item.
*/
static void nvgpu_clk_arb_worker_process_item(
struct nvgpu_clk_arb_work_item *work_item)
{
struct gk20a *g = work_item->arb->g;
clk_arb_dbg(g, " ");
if (work_item->item_type == CLK_ARB_WORK_UPDATE_VF_TABLE)
nvgpu_clk_arb_run_vf_table_cb(work_item->arb);
else if (work_item->item_type == CLK_ARB_WORK_UPDATE_ARB)
g->ops.clk_arb.clk_arb_run_arbiter_cb(work_item->arb);
}
/**
* Tell the worker that one more work needs to be done.
*
* Increase the work counter to synchronize the worker with the new work. Wake
* up the worker. If the worker was already running, it will handle this work
* before going to sleep.
*/
static int nvgpu_clk_arb_worker_wakeup(struct gk20a *g)
{
int put;
clk_arb_dbg(g, " ");
put = nvgpu_atomic_inc_return(&g->clk_arb_worker.put);
nvgpu_cond_signal_interruptible(&g->clk_arb_worker.wq);
return put;
}
/**
* Test if there is some work pending.
*
* This is a pair for nvgpu_clk_arb_worker_wakeup to be called from the
* worker. The worker has an internal work counter which is incremented once
* per finished work item. This is compared with the number of queued jobs.
*/
static bool nvgpu_clk_arb_worker_pending(struct gk20a *g, int get)
{
bool pending = nvgpu_atomic_read(&g->clk_arb_worker.put) != get;
/* We don't need barriers because they are implicit in locking */
return pending;
}
/**
* Process the queued works for the worker thread serially.
*
* Flush all the work items in the queue one by one. This may block timeout
* handling for a short while, as these are serialized.
*/
static void nvgpu_clk_arb_worker_process(struct gk20a *g, int *get)
{
while (nvgpu_clk_arb_worker_pending(g, *get)) {
struct nvgpu_clk_arb_work_item *work_item = NULL;
nvgpu_spinlock_acquire(&g->clk_arb_worker.items_lock);
if (!nvgpu_list_empty(&g->clk_arb_worker.items)) {
work_item = nvgpu_list_first_entry(&g->clk_arb_worker.items,
nvgpu_clk_arb_work_item, worker_item);
nvgpu_list_del(&work_item->worker_item);
}
nvgpu_spinlock_release(&g->clk_arb_worker.items_lock);
if (!work_item) {
/*
* Woke up for some other reason, but there are no
* other reasons than a work item added in the items list
* currently, so warn and ack the message.
*/
nvgpu_warn(g, "Spurious worker event!");
++*get;
break;
}
nvgpu_clk_arb_worker_process_item(work_item);
++*get;
}
}
/*
* Process all work items found in the clk arbiter work queue.
*/
static int nvgpu_clk_arb_poll_worker(void *arg)
{
struct gk20a *g = (struct gk20a *)arg;
struct gk20a_worker *worker = &g->clk_arb_worker;
int get = 0;
clk_arb_dbg(g, " ");
while (!nvgpu_thread_should_stop(&worker->poll_task)) {
int ret;
ret = NVGPU_COND_WAIT_INTERRUPTIBLE(
&worker->wq,
nvgpu_clk_arb_worker_pending(g, get), 0);
if (nvgpu_thread_should_stop(&worker->poll_task)) {
break;
}
if (ret == 0)
nvgpu_clk_arb_worker_process(g, &get);
}
return 0;
}
static int __nvgpu_clk_arb_worker_start(struct gk20a *g)
{
char thread_name[64];
int err = 0;
if (nvgpu_thread_is_running(&g->clk_arb_worker.poll_task))
return err;
nvgpu_mutex_acquire(&g->clk_arb_worker.start_lock);
/*
* Mutexes have implicit barriers, so there is no risk of a thread
* having a stale copy of the poll_task variable as the call to
* thread_is_running is volatile
*/
if (nvgpu_thread_is_running(&g->clk_arb_worker.poll_task)) {
nvgpu_mutex_release(&g->clk_arb_worker.start_lock);
return err;
}
snprintf(thread_name, sizeof(thread_name),
"nvgpu_clk_arb_poll_%s", g->name);
err = nvgpu_thread_create(&g->clk_arb_worker.poll_task, g,
nvgpu_clk_arb_poll_worker, thread_name);
nvgpu_mutex_release(&g->clk_arb_worker.start_lock);
return err;
}
/**
* Append a work item to the worker's list.
*
* This adds work item to the end of the list and wakes the worker
* up immediately. If the work item already existed in the list, it's not added,
* because in that case it has been scheduled already but has not yet been
* processed.
*/
void nvgpu_clk_arb_worker_enqueue(struct gk20a *g,
struct nvgpu_clk_arb_work_item *work_item)
{
clk_arb_dbg(g, " ");
/*
* Warn if worker thread cannot run
*/
if (WARN_ON(__nvgpu_clk_arb_worker_start(g))) {
nvgpu_warn(g, "clk arb worker cannot run!");
return;
}
nvgpu_spinlock_acquire(&g->clk_arb_worker.items_lock);
if (!nvgpu_list_empty(&work_item->worker_item)) {
/*
* Already queued, so will get processed eventually.
* The worker is probably awake already.
*/
nvgpu_spinlock_release(&g->clk_arb_worker.items_lock);
return;
}
nvgpu_list_add_tail(&work_item->worker_item, &g->clk_arb_worker.items);
nvgpu_spinlock_release(&g->clk_arb_worker.items_lock);
nvgpu_clk_arb_worker_wakeup(g);
}
/**
* Initialize the clk arb worker's metadata and start the background thread.
*/
int nvgpu_clk_arb_worker_init(struct gk20a *g)
{
int err;
nvgpu_atomic_set(&g->clk_arb_worker.put, 0);
nvgpu_cond_init(&g->clk_arb_worker.wq);
nvgpu_init_list_node(&g->clk_arb_worker.items);
nvgpu_spinlock_init(&g->clk_arb_worker.items_lock);
err = nvgpu_mutex_init(&g->clk_arb_worker.start_lock);
if (err)
goto error_check;
err = __nvgpu_clk_arb_worker_start(g);
error_check:
if (err) {
nvgpu_err(g, "failed to start clk arb poller thread");
return err;
}
return 0;
}
int nvgpu_clk_arb_init_arbiter(struct gk20a *g)
{
int err = 0;
if (!g->ops.clk.support_clk_freq_controller ||
!g->ops.clk_arb.get_arbiter_clk_domains) {
return 0;
}
nvgpu_mutex_acquire(&g->clk_arb_enable_lock);
err = g->ops.clk_arb.arbiter_clk_init(g);
nvgpu_mutex_release(&g->clk_arb_enable_lock);
return err;
}
bool nvgpu_clk_arb_has_active_req(struct gk20a *g)
{
return (nvgpu_atomic_read(&g->clk_arb_global_nr) > 0);
}
void nvgpu_clk_arb_send_thermal_alarm(struct gk20a *g)
{
nvgpu_clk_arb_schedule_alarm(g,
(0x1UL << NVGPU_EVENT_ALARM_THERMAL_ABOVE_THRESHOLD));
}
void nvgpu_clk_arb_schedule_alarm(struct gk20a *g, u32 alarm)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
nvgpu_clk_arb_set_global_alarm(g, alarm);
nvgpu_clk_arb_worker_enqueue(g, &arb->update_arb_work_item);
}
static void nvgpu_clk_arb_worker_deinit(struct gk20a *g)
{
nvgpu_atomic_inc(&g->clk_arb_worker.put);
nvgpu_mutex_acquire(&g->clk_arb_worker.start_lock);
nvgpu_thread_stop(&g->clk_arb_worker.poll_task);
nvgpu_mutex_release(&g->clk_arb_worker.start_lock);
}
void nvgpu_clk_arb_cleanup_arbiter(struct gk20a *g)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
nvgpu_mutex_acquire(&g->clk_arb_enable_lock);
if (arb) {
nvgpu_clk_arb_worker_deinit(g);
g->ops.clk_arb.clk_arb_cleanup(g->clk_arb);
}
nvgpu_mutex_release(&g->clk_arb_enable_lock);
}
int nvgpu_clk_arb_init_session(struct gk20a *g,
struct nvgpu_clk_session **_session)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
struct nvgpu_clk_session *session = *(_session);
clk_arb_dbg(g, " ");
if (!g->ops.clk.support_clk_freq_controller ||
!g->ops.clk_arb.get_arbiter_clk_domains) {
return 0;
}
session = nvgpu_kzalloc(g, sizeof(struct nvgpu_clk_session));
if (!session)
return -ENOMEM;
session->g = g;
nvgpu_ref_init(&session->refcount);
session->zombie = false;
session->target_pool[0].pstate = CTRL_PERF_PSTATE_P8;
/* make sure that the initialization of the pool is visible
* before the update
*/
nvgpu_smp_wmb();
session->target = &session->target_pool[0];
nvgpu_init_list_node(&session->targets);
nvgpu_spinlock_init(&session->session_lock);
nvgpu_spinlock_acquire(&arb->sessions_lock);
nvgpu_list_add_tail(&session->link, &arb->sessions);
nvgpu_spinlock_release(&arb->sessions_lock);
*_session = session;
return 0;
}
void nvgpu_clk_arb_free_fd(struct nvgpu_ref *refcount)
{
struct nvgpu_clk_dev *dev = container_of(refcount,
struct nvgpu_clk_dev, refcount);
struct nvgpu_clk_session *session = dev->session;
struct gk20a *g = session->g;
nvgpu_clk_notification_queue_free(g, &dev->queue);
nvgpu_atomic_dec(&g->clk_arb_global_nr);
nvgpu_kfree(g, dev);
}
void nvgpu_clk_arb_free_session(struct nvgpu_ref *refcount)
{
struct nvgpu_clk_session *session = container_of(refcount,
struct nvgpu_clk_session, refcount);
struct nvgpu_clk_arb *arb = session->g->clk_arb;
struct gk20a *g = session->g;
struct nvgpu_clk_dev *dev, *tmp;
clk_arb_dbg(g, " ");
if (arb) {
nvgpu_spinlock_acquire(&arb->sessions_lock);
nvgpu_list_del(&session->link);
nvgpu_spinlock_release(&arb->sessions_lock);
}
nvgpu_spinlock_acquire(&session->session_lock);
nvgpu_list_for_each_entry_safe(dev, tmp, &session->targets,
nvgpu_clk_dev, node) {
nvgpu_ref_put(&dev->refcount, nvgpu_clk_arb_free_fd);
nvgpu_list_del(&dev->node);
}
nvgpu_spinlock_release(&session->session_lock);
nvgpu_kfree(g, session);
}
void nvgpu_clk_arb_release_session(struct gk20a *g,
struct nvgpu_clk_session *session)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
clk_arb_dbg(g, " ");
session->zombie = true;
nvgpu_ref_put(&session->refcount, nvgpu_clk_arb_free_session);
if (arb)
nvgpu_clk_arb_worker_enqueue(g, &arb->update_arb_work_item);
}
void nvgpu_clk_arb_schedule_vf_table_update(struct gk20a *g)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
nvgpu_clk_arb_worker_enqueue(g, &arb->update_vf_table_work_item);
}
/* This function is inherently unsafe to call while arbiter is running
* arbiter must be blocked before calling this function
*/
int nvgpu_clk_arb_get_current_pstate(struct gk20a *g)
{
return NV_ACCESS_ONCE(g->clk_arb->actual->pstate);
}
void nvgpu_clk_arb_pstate_change_lock(struct gk20a *g, bool lock)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
if (lock)
nvgpu_mutex_acquire(&arb->pstate_lock);
else
nvgpu_mutex_release(&arb->pstate_lock);
}
bool nvgpu_clk_arb_is_valid_domain(struct gk20a *g, u32 api_domain)
{
u32 clk_domains = g->ops.clk_arb.get_arbiter_clk_domains(g);
switch (api_domain) {
case NVGPU_CLK_DOMAIN_MCLK:
return (clk_domains & CTRL_CLK_DOMAIN_MCLK) != 0;
case NVGPU_CLK_DOMAIN_GPCCLK:
return (clk_domains & CTRL_CLK_DOMAIN_GPC2CLK) != 0;
default:
return false;
}
}
int nvgpu_clk_arb_get_arbiter_clk_range(struct gk20a *g, u32 api_domain,
u16 *min_mhz, u16 *max_mhz)
{
int ret;
switch (api_domain) {
case NVGPU_CLK_DOMAIN_MCLK:
ret = g->ops.clk_arb.get_arbiter_clk_range(g,
CTRL_CLK_DOMAIN_MCLK, min_mhz, max_mhz);
return ret;
case NVGPU_CLK_DOMAIN_GPCCLK:
ret = g->ops.clk_arb.get_arbiter_clk_range(g,
CTRL_CLK_DOMAIN_GPC2CLK, min_mhz, max_mhz);
if (!ret) {
*min_mhz /= 2;
*max_mhz /= 2;
}
return ret;
default:
return -EINVAL;
}
}
int nvgpu_clk_arb_get_arbiter_clk_f_points(struct gk20a *g,
u32 api_domain, u32 *max_points, u16 *fpoints)
{
int err;
u32 i;
switch (api_domain) {
case NVGPU_CLK_DOMAIN_GPCCLK:
err = g->ops.clk_arb.get_arbiter_f_points(g,
CTRL_CLK_DOMAIN_GPC2CLK, max_points, fpoints);
if (err || !fpoints)
return err;
for (i = 0; i < *max_points; i++)
fpoints[i] /= 2;
return 0;
case NVGPU_CLK_DOMAIN_MCLK:
return g->ops.clk_arb.get_arbiter_f_points(g,
CTRL_CLK_DOMAIN_MCLK, max_points, fpoints);
default:
return -EINVAL;
}
}
int nvgpu_clk_arb_get_session_target_mhz(struct nvgpu_clk_session *session,
u32 api_domain, u16 *freq_mhz)
{
int err = 0;
struct nvgpu_clk_arb_target *target = session->target;
if (!nvgpu_clk_arb_is_valid_domain(session->g, api_domain)) {
return -EINVAL;
}
switch (api_domain) {
case NVGPU_CLK_DOMAIN_MCLK:
*freq_mhz = target->mclk;
break;
case NVGPU_CLK_DOMAIN_GPCCLK:
*freq_mhz = target->gpc2clk / 2ULL;
break;
default:
*freq_mhz = 0;
err = -EINVAL;
}
return err;
}
int nvgpu_clk_arb_get_arbiter_actual_mhz(struct gk20a *g,
u32 api_domain, u16 *freq_mhz)
{
struct nvgpu_clk_arb *arb = g->clk_arb;
int err = 0;
struct nvgpu_clk_arb_target *actual = arb->actual;
if (!nvgpu_clk_arb_is_valid_domain(g, api_domain)) {
return -EINVAL;
}
switch (api_domain) {
case NVGPU_CLK_DOMAIN_MCLK:
*freq_mhz = actual->mclk;
break;
case NVGPU_CLK_DOMAIN_GPCCLK:
*freq_mhz = actual->gpc2clk / 2ULL;
break;
default:
*freq_mhz = 0;
err = -EINVAL;
}
return err;
}
unsigned long nvgpu_clk_measure_freq(struct gk20a *g, u32 api_domain)
{
unsigned long freq = 0UL;
switch (api_domain) {
case CTRL_CLK_DOMAIN_GPC2CLK:
freq = g->ops.clk.get_rate(g, CTRL_CLK_DOMAIN_GPCCLK) * 2UL;
break;
default:
break;
}
return freq;
}
int nvgpu_clk_arb_get_arbiter_effective_mhz(struct gk20a *g,
u32 api_domain, u16 *freq_mhz)
{
if (!nvgpu_clk_arb_is_valid_domain(g, api_domain)) {
return -EINVAL;
}
switch (api_domain) {
case NVGPU_CLK_DOMAIN_MCLK:
*freq_mhz = g->ops.clk.measure_freq(g, CTRL_CLK_DOMAIN_MCLK) /
1000000ULL;
return 0;
case NVGPU_CLK_DOMAIN_GPCCLK:
*freq_mhz = g->ops.clk.measure_freq(g,
CTRL_CLK_DOMAIN_GPC2CLK) / 2000000ULL;
return 0;
default:
return -EINVAL;
}
}
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