blob: 86adbb66abab7e4667239203267bb53c37c10717 [file] [log] [blame]
/*
**************************************************************************
* Copyright (c) 2013, 2015-2017 The Linux Foundation. All rights reserved.
* Permission to use, copy, modify, and/or distribute this software for
* any purpose with or without fee is hereby granted, provided that the
* above copyright notice and this permission notice appear in all copies.
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT
* OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
**************************************************************************
*/
/*
* nss_freq.c
* NSS frequency change APIs
*/
#include "nss_tx_rx_common.h"
#define NSS_ACK_STARTED 0
#define NSS_ACK_FINISHED 1
extern struct nss_frequency_statistics nss_freq_stat;
extern struct nss_runtime_sampling nss_runtime_samples;
extern struct workqueue_struct *nss_wq;
extern nss_work_t *nss_work;
/*
* nss_freq_msg_init()
* Initialize the freq message
*/
static void nss_freq_msg_init(struct nss_corefreq_msg *ncm, uint16_t if_num, uint32_t type, uint32_t len,
void *cb, void *app_data)
{
nss_cmn_msg_init(&ncm->cm, if_num, type, len, cb, app_data);
}
/*
* nss_freq_handle_ack()
* Handle the nss ack of frequency change.
*/
static void nss_freq_handle_ack(struct nss_ctx_instance *nss_ctx, struct nss_freq_msg *nfa)
{
if (nfa->ack == NSS_ACK_STARTED) {
/*
* NSS finished start noficiation - HW change clocks and send end notification
*/
nss_info("%p: NSS ACK Received: %d - Change HW CLK/Send Finish to NSS\n", nss_ctx, nfa->ack);
return;
}
if (nfa->ack == NSS_ACK_FINISHED) {
/*
* NSS finished end notification - Done
*/
nss_info("%p: NSS ACK Received: %d - End Notification ACK - Running: %dmhz\n", nss_ctx, nfa->ack, nfa->freq_current);
nss_runtime_samples.freq_scale_ready = 1;
return;
}
nss_info("%p: NSS had an error - Running: %dmhz\n", nss_ctx, nfa->freq_current);
}
/*
* nss_freq_queue_work()
* Queue Work to the NSS Workqueue based on Current index.
*/
static bool nss_freq_queue_work(void)
{
nss_freq_scales_t index = nss_runtime_samples.freq_scale_index;
BUG_ON(!nss_wq);
nss_info("frequency:%d index:%d sample count:%x\n", nss_runtime_samples.freq_scale[index].frequency,
index, nss_runtime_samples.average);
/*
* schedule freq change with autoscale ON
*/
return nss_freq_sched_change(index, true);
}
/*
* nss_freq_handle_core_stats()
* Handle the core stats
*/
static void nss_freq_handle_core_stats(struct nss_ctx_instance *nss_ctx, struct nss_core_stats *core_stats)
{
uint32_t b_index;
uint32_t minimum;
uint32_t maximum;
uint32_t sample = core_stats->inst_cnt_total;
uint32_t index = nss_runtime_samples.freq_scale_index;
/*
* We do not accept any statistics if auto scaling is off,
* we start with a fresh sample set when scaling is
* eventually turned on.
*/
if (!nss_cmd_buf.auto_scale && nss_runtime_samples.initialized) {
return;
}
/*
* Delete Current Index Value, Add New Value, Recalculate new Sum, Shift Index
*/
b_index = nss_runtime_samples.buffer_index;
nss_runtime_samples.sum = nss_runtime_samples.sum - nss_runtime_samples.buffer[b_index];
nss_runtime_samples.buffer[b_index] = sample;
nss_runtime_samples.sum = nss_runtime_samples.sum + nss_runtime_samples.buffer[b_index];
nss_runtime_samples.buffer_index = (b_index + 1) & NSS_SAMPLE_BUFFER_MASK;
if (nss_runtime_samples.sample_count < NSS_SAMPLE_BUFFER_SIZE) {
nss_runtime_samples.sample_count++;
/*
* Samples Are All Ready, Start Auto Scale
*/
if (nss_runtime_samples.sample_count == NSS_SAMPLE_BUFFER_SIZE ) {
nss_cmd_buf.auto_scale = 1;
nss_runtime_samples.freq_scale_ready = 1;
nss_runtime_samples.initialized = 1;
}
return;
}
nss_runtime_samples.average = nss_runtime_samples.sum / nss_runtime_samples.sample_count;
/*
* Print out statistics every 10 samples
*/
if (nss_runtime_samples.message_rate_limit++ >= NSS_MESSAGE_RATE_LIMIT) {
nss_trace("%p: Running AVG:%x Sample:%x Divider:%d\n", nss_ctx, nss_runtime_samples.average, core_stats->inst_cnt_total, nss_runtime_samples.sample_count);
nss_trace("%p: Current Frequency Index:%d\n", nss_ctx, index);
nss_trace("%p: Auto Scale:%d Auto Scale Ready:%d\n", nss_ctx, nss_runtime_samples.freq_scale_ready, nss_cmd_buf.auto_scale);
nss_trace("%p: Current Rate:%x\n", nss_ctx, nss_runtime_samples.average);
nss_runtime_samples.message_rate_limit = 0;
}
/*
* Don't scale if we are not ready or auto scale is disabled.
*/
if ((nss_runtime_samples.freq_scale_ready != 1) || (nss_cmd_buf.auto_scale != 1)) {
return;
}
/*
* Scale Algorithmn
* Algorithmn will limit how fast it will transition each scale, by the number of samples seen.
* If any sample is out of scale during the idle count, the rate_limit will reset to 0.
* Scales are limited to the max number of cpu scales we support.
*/
if (nss_runtime_samples.freq_scale_rate_limit_up++ >= NSS_FREQUENCY_SCALE_RATE_LIMIT_UP) {
maximum = nss_runtime_samples.freq_scale[index].maximum;
if ((nss_runtime_samples.average > maximum) && (index < (NSS_FREQ_MAX_SCALE - 1))) {
nss_runtime_samples.freq_scale_index++;
nss_runtime_samples.freq_scale_ready = 0;
/*
* If fail to increase frequency, decrease index
*/
nss_trace("frequency increase to %d inst:%x > maximum:%x\n", nss_runtime_samples.freq_scale[nss_runtime_samples.freq_scale_index].frequency, sample, maximum);
if (!nss_freq_queue_work()) {
nss_runtime_samples.freq_scale_index--;
}
}
/*
* Reset the down scale counter based on running average, so can idle properlly
*/
if (nss_runtime_samples.average > maximum) {
nss_trace("down scale timeout reset running average:%x\n", nss_runtime_samples.average);
nss_runtime_samples.freq_scale_rate_limit_down = 0;
}
nss_runtime_samples.freq_scale_rate_limit_up = 0;
return;
}
if (nss_runtime_samples.freq_scale_rate_limit_down++ >= NSS_FREQUENCY_SCALE_RATE_LIMIT_DOWN) {
minimum = nss_runtime_samples.freq_scale[index].minimum;
if ((nss_runtime_samples.average < minimum) && (index > 0)) {
nss_runtime_samples.freq_scale_index--;
nss_runtime_samples.freq_scale_ready = 0;
/*
* If fail to decrease frequency, increase index
*/
nss_trace("frequency decrease to %d inst:%x < minumum:%x\n", nss_runtime_samples.freq_scale[nss_runtime_samples.freq_scale_index].frequency, nss_runtime_samples.average, minimum);
if (!nss_freq_queue_work()) {
nss_runtime_samples.freq_scale_index++;
}
}
nss_runtime_samples.freq_scale_rate_limit_down = 0;
return;
}
}
/*
* nss_freq_interface_handler()
* Handle NSS -> HLOS messages for Frequency Changes and Statistics
*/
static void nss_freq_interface_handler(struct nss_ctx_instance *nss_ctx, struct nss_cmn_msg *ncm, __attribute__((unused))void *app_data) {
struct nss_corefreq_msg *ncfm = (struct nss_corefreq_msg *)ncm;
switch (ncfm->cm.type) {
case COREFREQ_METADATA_TYPE_TX_FREQ_ACK:
nss_freq_handle_ack(nss_ctx, &ncfm->msg.nfc);
break;
case COREFREQ_METADATA_TYPE_TX_CORE_STATS:
nss_freq_handle_core_stats(nss_ctx, &ncfm->msg.ncs);
break;
default:
if (ncm->response != NSS_CMN_RESPONSE_ACK) {
/*
* Check response
*/
nss_info("%p: Received response %d for type %d, interface %d", nss_ctx, ncm->response, ncm->type, ncm->interface);
}
}
}
/*
* nss_freq_change()
* NSS frequency change API.
*/
nss_tx_status_t nss_freq_change(struct nss_ctx_instance *nss_ctx, uint32_t eng, uint32_t stats_enable, uint32_t start_or_end)
{
struct sk_buff *nbuf;
int32_t status;
struct nss_corefreq_msg *ncm;
struct nss_freq_msg *nfc;
nss_info("%p: frequency changing to: %d\n", nss_ctx, eng);
NSS_VERIFY_CTX_MAGIC(nss_ctx);
if (unlikely(nss_ctx->state != NSS_CORE_STATE_INITIALIZED)) {
return NSS_TX_FAILURE_NOT_READY;
}
nbuf = dev_alloc_skb(NSS_NBUF_PAYLOAD_SIZE);
if (unlikely(!nbuf)) {
NSS_PKT_STATS_INCREMENT(nss_ctx, &nss_ctx->nss_top->stats_drv[NSS_STATS_DRV_NBUF_ALLOC_FAILS]);
return NSS_TX_FAILURE;
}
ncm = (struct nss_corefreq_msg *)skb_put(nbuf, sizeof(struct nss_corefreq_msg));
nss_freq_msg_init(ncm, NSS_COREFREQ_INTERFACE, NSS_TX_METADATA_TYPE_NSS_FREQ_CHANGE,
sizeof(struct nss_freq_msg), NULL, NULL);
nfc = &ncm->msg.nfc;
nfc->frequency = eng;
nfc->start_or_end = start_or_end;
nfc->stats_enable = stats_enable;
status = nss_core_send_buffer(nss_ctx, 0, nbuf, NSS_IF_CMD_QUEUE, H2N_BUFFER_CTRL, 0);
if (status != NSS_CORE_STATUS_SUCCESS) {
dev_kfree_skb_any(nbuf);
nss_info("%p: unable to enqueue 'nss frequency change' - marked as stopped\n", nss_ctx);
return NSS_TX_FAILURE;
}
nss_hal_send_interrupt(nss_ctx, NSS_H2N_INTR_DATA_COMMAND_QUEUE);
return NSS_TX_SUCCESS;
}
/*
* nss_freq_sched_change()
* schedule a frequency work
*/
bool nss_freq_sched_change(nss_freq_scales_t index, bool auto_scale)
{
if (index >= NSS_FREQ_MAX_SCALE) {
nss_info("NSS freq scale beyond limit\n");
return false;
}
nss_work = (nss_work_t *)kmalloc(sizeof(nss_work_t), GFP_ATOMIC);
if (!nss_work) {
nss_info("NSS Freq WQ kmalloc fail");
return false;
}
INIT_WORK((struct work_struct *)nss_work, nss_wq_function);
nss_work->frequency = nss_runtime_samples.freq_scale[index].frequency;
nss_work->stats_enable = auto_scale;
nss_cmd_buf.current_freq = nss_work->frequency;
queue_work(nss_wq, (struct work_struct *)nss_work);
return true;
}
/*
* nss_freq_register_handler()
*/
void nss_freq_register_handler(void)
{
nss_core_register_handler(NSS_COREFREQ_INTERFACE, nss_freq_interface_handler, NULL);
}