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/**
* Self Test application for Invensense's MPU6050/MPU9150.
*/
#include <unistd.h>
#include <dirent.h>
#include <fcntl.h>
#include <stdio.h>
#include <errno.h>
#include <sys/stat.h>
#include <stdlib.h>
#include <features.h>
#include <dirent.h>
#include <string.h>
#include <poll.h>
#include <stddef.h>
#include <linux/input.h>
#include <time.h>
#include <linux/time.h>
#include "invensense.h"
#include "ml_math_func.h"
#include "storage_manager.h"
#include "ml_stored_data.h"
#ifndef ABS
#define ABS(x)(((x) >= 0) ? (x) : -(x))
#endif
/** Change this key if the data being stored by this file changes */
#define INV_DB_SAVE_KEY 53394
#define FALSE 0
#define TRUE 1
#define GYRO_PASS_STATUS_BIT 0x01
#define ACCEL_PASS_STATUS_BIT 0x02
#define COMPASS_PASS_STATUS_BIT 0x04
typedef union {
long l;
int i;
} bias_dtype;
struct inv_sysfs_names_s {
char *enable;
char *power_state;
char *self_test;
char *temperature;
char *accl_bias;
};
const struct inv_sysfs_names_s mpu= {
/* MPU6050 & MPU9150 */
.enable = "/sys/class/invensense/mpu/enable",
.power_state = "/sys/class/invensense/mpu/power_state",
.self_test = "/sys/class/invensense/mpu/self_test",
.temperature = "/sys/class/invensense/mpu/temperature",
.accl_bias = "/sys/class/invensense/mpu/accl_bias"
};
struct inv_db_save_t {
/** Compass Bias in Chip Frame in Hardware units scaled by 2^16 */
long compass_bias[3];
/** Gyro Bias in Chip Frame in Hardware units scaled by 2^16 */
long gyro_bias[3];
/** Temperature when *gyro_bias was stored. */
long gyro_temp;
/** Accel Bias in Chip Frame in Hardware units scaled by 2^16 */
long accel_bias[3];
/** Temperature when accel bias was stored. */
long accel_temp;
long gyro_temp_slope[3];
};
static struct inv_db_save_t save_data;
/** This function receives the data that was stored in non-volatile memory between power off */
static inv_error_t inv_db_load_func(const unsigned char *data)
{
memcpy(&save_data, data, sizeof(save_data));
return INV_SUCCESS;
}
/** This function returns the data to be stored in non-volatile memory between power off */
static inv_error_t inv_db_save_func(unsigned char *data)
{
memcpy(data, &save_data, sizeof(save_data));
return INV_SUCCESS;
}
int inv_sysfs_write(char *filename, long data)
{
FILE *fp;
int count;
if (!filename)
return -1;
fp = fopen(filename, "w");
if (!fp)
return -errno;
count = fprintf(fp, "%ld", data);
fclose(fp);
return count;
}
/**
* Main Self test
*/
int main(int argc, char **argv)
{
FILE *fptr;
int self_test_status;
inv_error_t result;
bias_dtype gyro_bias[3];
bias_dtype accel_bias[3];
int axis = 0;
size_t packet_sz;
int axis_sign = 1;
unsigned char *buffer;
long timestamp;
int temperature=0;
// Initialize storage manager
inv_init_storage_manager();
// Clear out data.
memset(&save_data, 0, sizeof(save_data));
memset(gyro_bias,0, sizeof(gyro_bias));
memset(accel_bias,0, sizeof(accel_bias));
// Register packet to be saved.
result = inv_register_load_store(inv_db_load_func, inv_db_save_func,
sizeof(save_data),
INV_DB_SAVE_KEY);
// Power ON MPUxxxx chip
if (inv_sysfs_write(mpu.power_state, 1) <0) {
printf("ERR- Failed to set power state=1\n");
} else {
// Note: Driver turns on power automatically when self-test invoked
}
fptr = fopen(mpu.self_test, "r");
if (fptr != NULL) {
// Invoke self-test and read gyro bias
fscanf(fptr, "%d,%d,%d,%d",
&gyro_bias[0].i, &gyro_bias[1].i, &gyro_bias[2].i, &self_test_status);
printf("Self-Test:Self test result- Gyro passed= %x, Accel passed= %x, Compass passed= %x\n",
(self_test_status & GYRO_PASS_STATUS_BIT),
(self_test_status & ACCEL_PASS_STATUS_BIT) >>1,
(self_test_status & COMPASS_PASS_STATUS_BIT) >>2);
printf("Self-Test:Gyro bias data[0..2] read from Driver= [%d %d %d]\n",gyro_bias[0].i, gyro_bias[1].i, gyro_bias[2].i);
fclose(fptr);
if (!(self_test_status & GYRO_PASS_STATUS_BIT)) {
// Reset gyro bias data if gyro self-test failed
memset(gyro_bias,0, sizeof(gyro_bias));
printf("Self-Test:Failed Gyro self-test\n");
}
if (self_test_status & ACCEL_PASS_STATUS_BIT) {
// Read Accel Bias
fptr= fopen(mpu.accl_bias, "r");
if (fptr != NULL) {
fscanf(fptr, "%d,%d,%d", &accel_bias[0].i, &accel_bias[1].i, &accel_bias[2].i);
printf("Self-Test:Accel bias data[0..2] read from Driver= [%d %d %d]\n", accel_bias[0].i, accel_bias[1].i, accel_bias[2].i);
fclose(fptr);
} else {
printf("Self-Test:ERR-Couldn't read accel bias\n");
}
} else {
memset(accel_bias,0, sizeof(accel_bias));
printf("Self-Test:Failed Accel self-test\n");
}
// Read temperature
if (self_test_status & (GYRO_PASS_STATUS_BIT|ACCEL_PASS_STATUS_BIT))
{
fptr= fopen(mpu.temperature, "r");
if (fptr != NULL) {
fscanf(fptr,"%d %ld", &temperature, ×tamp);
fclose(fptr);
} else {
printf("Self-Test:ERR-Couldn't read temperature\n");
}
}
} else {
printf("Self-Test:ERR-Couldn't invoke self-test\n");
}
// When we read gyro bias, the bias is in raw units scaled by 1000.
// We store the bias in raw units scaled by 2^16
save_data.gyro_bias[0] = (long)(gyro_bias[0].l * 65536.f / 8000.f);
save_data.gyro_bias[1] = (long)(gyro_bias[1].l * 65536.f / 8000.f);
save_data.gyro_bias[2] = (long)(gyro_bias[2].l * 65536.f / 8000.f);
// Save temperature @ time stored. Temperature is in degrees Celsius scaled by 2^16
save_data.gyro_temp = temperature * (1L << 16);
save_data.accel_temp = save_data.gyro_temp;
// When we read accel bias, the bias is in raw units scaled by 1000.
// and it contains the gravity vector.
// Find the orientation of the device, by looking for gravity
if (ABS(accel_bias[1].l) > ABS(accel_bias[0].l)) {
axis = 1;
}
if (ABS(accel_bias[2].l) > ABS(accel_bias[axis].l)) {
axis = 2;
}
if (accel_bias[axis].l < 0) {
axis_sign = -1;
}
// Remove gravity, gravity in raw units should be 16384 for a 2g setting.
// We read data scaled by 1000, so
accel_bias[axis].l -= axis_sign * 4096L * 1000L;
// Convert scaling from raw units scaled by 1000 to raw scaled by 2^16
save_data.accel_bias[0] = (long)(accel_bias[0].l * 65536.f / 1000.f * 4.f);
save_data.accel_bias[1] = (long)(accel_bias[1].l * 65536.f / 1000.f * 4.f);
save_data.accel_bias[2] = (long)(accel_bias[2].l * 65536.f / 1000.f * 4.f);
#if 1
printf("Self-Test:Saved Accel bias[0..2]= [%ld %ld %ld]\n", save_data.accel_bias[0],
save_data.accel_bias[1], save_data.accel_bias[2]);
printf("Self-Test:Saved Gyro bias[0..2]= [%ld %ld %ld]\n", save_data.gyro_bias[0],
save_data.gyro_bias[1], save_data.gyro_bias[2]);
printf("Self-Test:Gyro temperature @ time stored %ld\n", save_data.gyro_temp);
printf("Self-Test:Accel temperature @ time stored %ld\n", save_data.accel_temp);
#endif
// Get size of packet to store.
inv_get_mpl_state_size(&packet_sz);
// Create place to store data
buffer = (unsigned char *)malloc(packet_sz + 10);
if (buffer == NULL) {
printf("Self-Test:Can't allocate buffer\n");
return -1;
}
result = inv_save_mpl_states(buffer, packet_sz);
if (result) {
result= -1;
} else {
fptr= fopen(MLCAL_FILE, "wb+");
if (fptr != NULL) {
fwrite(buffer, 1, packet_sz, fptr);
fclose(fptr);
} else {
printf("Self-Test:ERR- Can't open calibration file to write - %s\n",
MLCAL_FILE);
result= -1;
}
}
free(buffer);
return result;
}
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