kernel_samsung_a34x-permissive/drivers/sensorhub/debug/shub_system_checker.c

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/*
* Copyright (C) 2020, Samsung Electronics Co. Ltd. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <linux/delay.h>
#include <linux/random.h>
#include <linux/slab.h>
#include "../comm/shub_comm.h"
#include "../sensormanager/shub_sensor.h"
#include "../sensormanager/shub_sensor_manager.h"
#include "../sensorhub/shub_device.h"
#include "../utility/shub_utility.h"
#include "shub_system_checker.h"
#ifdef CONFIG_SHUB_DEBUG
#define SSC_DEFAULT_DELAY (500)
#define SSC_DEFAULT_COUNT (50)
struct sensor_rate {
int32_t sampling_ms;
int32_t report_ms;
};
struct system_env_backup {
uint64_t pre_sensor_state;
struct sensor_rate pre_rate[SENSOR_TYPE_LEGACY_MAX];
int32_t pre_enabled_count[SENSOR_TYPE_LEGACY_MAX];
};
struct sensor_test_factor {
int32_t comm_test_response_cnt;
int32_t event_test_response_cnt;
int32_t order_test_response_cnt;
int32_t order_test_fail_cnt;
int32_t min_delay;
uint64_t expected_delay_ns;
uint64_t pre_event_timestamp;
uint64_t order_test_reversed_timestamp;
uint64_t standard_deviation;
uint64_t min_diff;
uint64_t max_diff;
};
struct system_check_data {
bool is_system_checking;
int32_t is_event_order_checking;
struct mutex system_test_mutex;
struct system_env_backup env_backup;
struct sensor_test_factor sensor[SENSOR_TYPE_LEGACY_MAX];
};
static struct system_check_data ssc;
static uint32_t ssc_delay_us;
static uint32_t ssc_count;
static inline void register_system_test_cb(void)
{
mutex_lock(&ssc.system_test_mutex);
ssc.is_system_checking = true;
mutex_unlock(&ssc.system_test_mutex);
}
static inline void unregister_system_test_cb(void)
{
mutex_lock(&ssc.system_test_mutex);
ssc.is_system_checking = false;
mutex_unlock(&ssc.system_test_mutex);
}
static inline void register_event_order_test_cb(void)
{
mutex_lock(&ssc.system_test_mutex);
ssc.is_event_order_checking = true;
mutex_unlock(&ssc.system_test_mutex);
}
static inline void unregister_event_order_test_cb(void)
{
mutex_lock(&ssc.system_test_mutex);
ssc.is_event_order_checking = false;
mutex_unlock(&ssc.system_test_mutex);
}
static void flush_all_sensors(void)
{
int32_t type = 0;
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
shub_send_command(CMD_GETVALUE, type, SENSOR_FLUSH, NULL, 0);
usleep_range(ssc_delay_us, ssc_delay_us * 2);
}
}
static void run_comm_test(void)
{
int32_t i;
shub_infof("[SSC] run comm test...");
register_system_test_cb();
for (i = 0; i < ssc_count; i++)
flush_all_sensors();
msleep(100);
unregister_system_test_cb();
}
static void set_sensors_sampling_rate(void)
{
int32_t type = 0, rate = 0;
struct shub_sensor *sensor = NULL;
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
sensor = get_sensor(type);
if (!sensor)
continue;
rate = (int32_t)(ssc.sensor[type].expected_delay_ns / 1000000);
sensor->sampling_period = sensor->max_report_latency = ssc.sensor[type].min_delay = rate;
}
}
static void run_event_test(void)
{
int32_t type = 0;
shub_infof("[SSC] run event test...");
set_sensors_sampling_rate();
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
ssc.sensor[type].min_diff = 0xffffffffffffffff;
ssc.sensor[type].max_diff = 0;
enable_sensor(type, NULL, 0);
usleep_range(500, 1000);
}
msleep(100);
register_system_test_cb();
msleep(1000);
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
disable_sensor(type, NULL, 0);
usleep_range(500, 1000);
}
unregister_system_test_cb();
}
int32_t order_test_types[3] = {SENSOR_TYPE_ACCELEROMETER, SENSOR_TYPE_GEOMAGNETIC_FIELD, SENSOR_TYPE_GYROSCOPE};
static uint32_t get_random(void)
{
uint32_t rand;
get_random_bytes(&rand, sizeof(uint32_t));
return rand;
}
static void enable_order_test_sensors(void)
{
int32_t type;
uint64_t i;
for (i = 0 ; i < ARRAY_SIZE(order_test_types) ; i++) {
type = order_test_types[i];
batch_sensor(type, ssc.sensor[type].min_delay, 0);
enable_sensor(type, NULL, 0);
usleep_range(500, 1000);
}
}
static void disable_order_test_sensors(void)
{
int32_t type;
uint64_t i;
for (i = 0 ; i < ARRAY_SIZE(order_test_types) ; i++) {
type = order_test_types[i];
disable_sensor(type, NULL, 0);
usleep_range(500, 1000);
}
}
static void run_event_order_test(void)
{
uint64_t i;
int32_t type;
int32_t sampling_rate = 5;
int32_t report_latency = 0;
int32_t test_cnt = ssc_count;
shub_infof("[SSC] run event order test...");
for (i = 0 ; i < ARRAY_SIZE(order_test_types) ; i++) {
type = order_test_types[i];
ssc.sensor[type].order_test_response_cnt = 0;
ssc.sensor[type].order_test_fail_cnt = 0;
ssc.sensor[type].order_test_reversed_timestamp = 0;
}
register_event_order_test_cb();
shub_infof("[SSC] sampling rate : fastest, report latency : random");
while (test_cnt--) {
shub_infof("[SSC] #%d", ssc_count - test_cnt);
enable_order_test_sensors();
msleep(2000);
for (i = 0 ; i < 100 ; i++) {
type = order_test_types[get_random() % 3];
sampling_rate = ssc.sensor[type].min_delay;
report_latency = (get_random() % 2) * 5000;
batch_sensor(type, sampling_rate, report_latency);
flush_sensor(type);
msleep(10 * (get_random() % 15));
}
disable_order_test_sensors();
}
test_cnt = ssc_count;
shub_infof("[SSC] sampling rate : random, report latency : random");
while (test_cnt--) {
shub_infof("[SSC] #%d", ssc_count - test_cnt);
enable_order_test_sensors();
for (i = 0 ; i < 100 ; i++) {
type = order_test_types[get_random() % 3];
sampling_rate = get_random() % 10;
if (sampling_rate == 0)
sampling_rate = ssc.sensor[type].min_delay;
else
sampling_rate = ssc.sensor[type].min_delay * sampling_rate;
report_latency = (get_random() % 6) * 1000;
batch_sensor(type, sampling_rate, report_latency);
flush_sensor(type);
msleep(10 * (get_random() % 15));
}
disable_order_test_sensors();
}
unregister_event_order_test_cb();
}
static void sensor_on_off(void)
{
int32_t type = 0;
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
enable_sensor(type, NULL, 0);
usleep_range(500, 1000);
disable_sensor(type, NULL, 0);
usleep_range(500, 1000);
}
}
static void run_system_test(void)
{
int32_t count = 0;
shub_infof("[SSC] run system test...");
shub_send_command(CMD_SETVALUE, TYPE_HUB, HUB_SYSTEM_CHECK, NULL, 0);
usleep_range(500, 1000);
for (count = 0 ; count < ssc_count; count++)
sensor_on_off();
}
void comm_test_cb(int32_t type)
{
ssc.sensor[type].comm_test_response_cnt++;
}
void event_test_cb(int32_t type, uint64_t timestamp)
{
uint64_t temp = 0;
if (type >= SENSOR_TYPE_LEGACY_MAX || type < SENSOR_TYPE_ACCELEROMETER)
return;
if (!ssc.sensor[type].pre_event_timestamp) {
ssc.sensor[type].pre_event_timestamp = timestamp;
return;
}
temp = timestamp - ssc.sensor[type].pre_event_timestamp;
temp = temp > ssc.sensor[type].expected_delay_ns ?
temp - ssc.sensor[type].expected_delay_ns : ssc.sensor[type].expected_delay_ns - temp;
ssc.sensor[type].min_diff = temp < ssc.sensor[type].min_diff ? temp : ssc.sensor[type].min_diff;
ssc.sensor[type].max_diff = temp > ssc.sensor[type].max_diff ? temp : ssc.sensor[type].max_diff;
ssc.sensor[type].standard_deviation += (temp * temp);
ssc.sensor[type].event_test_response_cnt++;
ssc.sensor[type].pre_event_timestamp = timestamp;
}
void order_test_cb(int32_t type, uint64_t timestamp)
{
if (!(type == SENSOR_TYPE_ACCELEROMETER || type == SENSOR_TYPE_GYROSCOPE ||
type == SENSOR_TYPE_GEOMAGNETIC_FIELD))
return;
if (!ssc.sensor[type].pre_event_timestamp || !timestamp) {
ssc.sensor[type].pre_event_timestamp = timestamp;
return;
}
if (ssc.sensor[type].pre_event_timestamp >= timestamp) {
ssc.sensor[type].order_test_reversed_timestamp = timestamp;
ssc.sensor[type].order_test_fail_cnt++;
shub_errf("[SSC] reversed type : %d, prev : %lld, curr : %lld",
type, ssc.sensor[type].pre_event_timestamp, timestamp);
}
ssc.sensor[type].order_test_response_cnt++;
//shub_infof("[SSC] type : %d, prev : %lld, curr : %lld",
// type, ssc.sensor[type].pre_event_timestamp, timestamp);
ssc.sensor[type].pre_event_timestamp = timestamp;
}
static void restore_test_env(void)
{
int32_t type = 0;
struct shub_sensor *sensor;
shub_infof("");
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
sensor = get_sensor(type);
if (sensor) {
mutex_lock(&sensor->enabled_mutex);
sensor->enabled = (ssc.env_backup.pre_sensor_state & (1ULL << type));
sensor->enabled_cnt = ssc.env_backup.pre_enabled_count[type];
mutex_unlock(&sensor->enabled_mutex);
sensor->sampling_period = ssc.env_backup.pre_rate[type].sampling_ms;
sensor->max_report_latency = ssc.env_backup.pre_rate[type].report_ms;
}
}
}
static uint64_t test_sqrt(uint64_t in)
{
int32_t count = 30;
uint64_t out = 1;
while (count-- > 0)
out = (out + in / out) / 2;
return out;
}
static void report_test_result(void)
{
enum system_test_op {
OPERATION_OPEN = 0,
OPERATION_READ,
OPERATION_CLOSE,
OPERATION_MAX,
};
struct sensor_debug_factor {
int32_t count;
uint64_t tt_sum;
uint64_t tt_max;
uint64_t tt_min;
} __attribute__((__packed__));
struct system_test {
uint8_t type;
struct sensor_debug_factor op[OPERATION_MAX];
} __attribute__((__packed__));
int32_t ret = 0;
int32_t i = 0;
int32_t type = 0;
int32_t count = 0;
int32_t index = 0;
int32_t buffer_length = 0;
int8_t *buffer = NULL;
shub_infof("[SSC] == comm test result ======");
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
shub_infof("[SSC] sensor(%2d) : %d", type, ssc.sensor[type].comm_test_response_cnt);
if (ssc.sensor[type].comm_test_response_cnt != ssc_count)
shub_infof("sensor(%d) failed!!", type);
}
shub_infof("[SSC] == event test result ======");
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
if (!get_sensor_probe_state(type))
continue;
shub_infof("[SSC] sensor(%2d) : cnt(%4d) std dev(%6lld), min(%6lld), max(%6lld)",
type,
ssc.sensor[type].event_test_response_cnt,
test_sqrt(
ssc.sensor[type].standard_deviation / ssc.sensor[type].event_test_response_cnt),
ssc.sensor[type].min_diff,
ssc.sensor[type].max_diff);
}
shub_infof("[SSC] == system test result ======");
ret = shub_send_command_wait(CMD_GETVALUE, TYPE_HUB, HUB_SYSTEM_CHECK,
1000, NULL, 0, (char **)&buffer, &buffer_length, true);
if (ret < 0 || !buffer || buffer_length == 0) {
shub_infof("[SSC] ERROR! Fail to get system test result!!");
return;
}
count = buffer[0];
index++;
for (type = 0; type < count; type++) {
struct system_test *result = (struct system_test *)(buffer + index);
index += sizeof(struct system_test);
shub_infof("[SSC] sensor(%2d)", result->type);
shub_infof("[SSC] OPEN - cnt(%4d) min(%7lld), max(%7lld), avg(%7lld)",
result->op[OPERATION_OPEN].count,
result->op[OPERATION_OPEN].tt_min,
result->op[OPERATION_OPEN].tt_max,
result->op[OPERATION_OPEN].tt_sum / result->op[OPERATION_OPEN].count);
shub_infof("[SSC] READ - cnt(%4d) min(%7lld), max(%7lld), avg(%7lld)",
result->op[OPERATION_READ].count,
result->op[OPERATION_READ].tt_min,
result->op[OPERATION_READ].tt_max,
result->op[OPERATION_READ].tt_sum / result->op[OPERATION_READ].count);
shub_infof("[SSC] CLOSE - cnt(%4d) min(%7lld), max(%7lld), avg(%7lld)",
result->op[OPERATION_CLOSE].count,
result->op[OPERATION_CLOSE].tt_min,
result->op[OPERATION_CLOSE].tt_max,
result->op[OPERATION_CLOSE].tt_sum / result->op[OPERATION_CLOSE].count);
}
shub_infof("[SSC] == event order test result ======");
for (i = 0 ; i < ARRAY_SIZE(order_test_types); i++) {
type = order_test_types[i];
shub_infof("[SSC] sensor(%2d)", type);
shub_infof("[SSC] ORDER - cnt(%4d) fail cnt(%4d), last reversed timestamp(%7lld)",
ssc.sensor[type].order_test_response_cnt, ssc.sensor[type].order_test_fail_cnt,
ssc.sensor[type].order_test_reversed_timestamp);
}
kfree(buffer);
}
void run_system_check(void)
{
static int32_t test_cnt = 1;
shub_infof("[SSC] !! #%d test begin !!!!!!!!!!!!!!!!!!", test_cnt++);
shub_infof("[SSC] !! DELAY(%dusec) COUNT(%d)", ssc_delay_us, ssc_count);
run_system_test();
run_comm_test();
run_event_test();
run_event_order_test();
usleep_range(500, 1000);
restore_test_env();
report_test_result();
reset_mcu(RESET_TYPE_KERNEL_SYSFS);
}
void system_ready_cb(void)
{
unregister_system_test_cb();
unregister_event_order_test_cb();
run_system_check();
}
static void prepare_test_env(void)
{
int32_t type = 0;
struct shub_sensor *sensor;
shub_infof("");
// init check_system data
memset(&ssc, 0, sizeof(ssc));
// backup shub env
ssc.env_backup.pre_sensor_state = get_sensors_legacy_enable_state();
for (type = SENSOR_TYPE_ACCELEROMETER; type < SENSOR_TYPE_LEGACY_MAX; type++) {
sensor = get_sensor(type);
if (sensor) {
ssc.env_backup.pre_enabled_count[type] = sensor->enabled_cnt;
mutex_lock(&sensor->enabled_mutex);
sensor->enabled = false;
sensor->enabled_cnt = 0;
mutex_unlock(&sensor->enabled_mutex);
ssc.env_backup.pre_rate[type].sampling_ms = sensor->sampling_period;
ssc.env_backup.pre_rate[type].report_ms = sensor->max_report_latency;
ssc.sensor[type].expected_delay_ns = sensor->spec.min_delay * 1000;
}
}
}
void sensorhub_system_check(uint32_t test_delay_us, uint32_t test_count)
{
ssc_delay_us = test_delay_us && test_delay_us < 5000 ? test_delay_us : SSC_DEFAULT_DELAY;
ssc_count = test_count && test_count < 100 ? test_count : SSC_DEFAULT_COUNT;
prepare_test_env();
register_system_test_cb();
reset_mcu(RESET_TYPE_KERNEL_SYSFS);
}
void shub_system_checker_init(void)
{
mutex_init(&ssc.system_test_mutex);
}
bool is_system_checking(void)
{
return ssc.is_system_checking;
}
bool is_event_order_checking(void)
{
return ssc.is_event_order_checking;
}
void shub_system_check_lock(void)
{
mutex_lock(&ssc.system_test_mutex);
}
void shub_system_check_unlock(void)
{
mutex_unlock(&ssc.system_test_mutex);
}
#endif