/*
ChibiOS - Copyright (C) 2016 Rocco Marco Guglielmi
This file is part of ChibiOS.
ChibiOS 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 3 of the License, or
(at your option) any later version.
ChibiOS 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.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/**
* @file lsm303dlhc.c
* @brief LSM303DLHC MEMS interface module code.
*
* @addtogroup lsm303dlhc
* @{
*/
#include "hal.h"
#include "lsm303dlhc.h"
/*===========================================================================*/
/* Driver local definitions. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver exported variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver local variables and types. */
/*===========================================================================*/
/**
* @brief Accelerometer Power Mode
*/
typedef enum {
LSM303DLHC_ACC_PM_NORMAL = 0x00, /**< Normal mode enabled */
LSM303DLHC_ACC_PM_LP = 0x08 /**< Low Power mode enabled */
} lsm303dlhc_acc_pm_t;
/**
* @brief Accelerometer and Compass Slave Address.
*/
typedef enum {
LSM303DLHC_SAD_ACC = 0x19, /**< SAD for accelerometer. */
LSM303DLHC_SAD_COMP = 0x1E /**< SAD for compass. */
} lsm303dlhc_sad_t;
/*===========================================================================*/
/* Driver local functions. */
/*===========================================================================*/
/**
* @brief Reads registers value using I2C.
* @pre The I2C interface must be initialized and the driver started.
* @note IF_ADD_INC bit must be 1 in CTRL_REG8
*
* @param[in] i2cp pointer to the I2C interface
* @param[in] sad slave address without R bit
* @param[in] reg first sub-register address
* @param[in] rxbuf receiving buffer
* @param[in] n size of rxbuf
* @return the operation status.
*/
msg_t lsm303dlhcI2CReadRegister(I2CDriver *i2cp, lsm303dlhc_sad_t sad,
uint8_t reg, uint8_t *rxbuf, size_t n) {
uint8_t txbuf = reg | LSM303DLHC_MS;
return i2cMasterTransmitTimeout(i2cp, sad, &txbuf, 1, rxbuf, n,
TIME_INFINITE);
}
/**
* @brief Writes a value into a register using I2C.
* @pre The I2C interface must be initialized and the driver started.
*
* @param[in] i2cp pointer to the I2C interface
* @param[in] sad slave address without R bit
* @param[in] txbuf buffer containing sub-address value in first position
* and values to write
* @param[in] n size of txbuf less one (not considering the first
* element)
* @return the operation status.
*/
msg_t lsm303dlhcI2CWriteRegister(I2CDriver *i2cp, lsm303dlhc_sad_t sad,
uint8_t *txbuf, size_t n) {
if (n != 1)
*txbuf |= LSM303DLHC_MS;
return i2cMasterTransmitTimeout(i2cp, sad, txbuf, n + 1, NULL, 0, TIME_INFINITE);
}
/*
* Interface implementation.
*/
static size_t acc_get_axes_number(void *ip) {
osalDbgCheck(ip != NULL);
return LSM303DLHC_ACC_NUMBER_OF_AXES;
}
static size_t comp_get_axes_number(void *ip) {
osalDbgCheck(ip != NULL);
return LSM303DLHC_COMP_NUMBER_OF_AXES;
}
static size_t sens_get_axes_number(void *ip) {
size_t size = 0;
osalDbgCheck(ip != NULL);
if (((LSM303DLHCDriver *)ip)->config->acccfg != NULL)
size += acc_get_axes_number(ip);
if (((LSM303DLHCDriver *)ip)->config->compcfg != NULL)
size += comp_get_axes_number(ip);
return size;
}
static msg_t acc_read_raw(void *ip, int32_t axes[]) {
uint8_t buff [LSM303DLHC_ACC_NUMBER_OF_AXES * 2], i;
int16_t tmp;
msg_t msg;
osalDbgCheck(((ip != NULL) && (axes != NULL)) &&
(((LSM303DLHCDriver *)ip)->config->acccfg != NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"acc_read_raw(), invalid state");
osalDbgAssert((((LSM303DLHCDriver *)ip)->config->i2cp->state == I2C_READY),
"acc_read_raw(), channel not ready");
#if LSM303DLHC_SHARED_I2C
i2cAcquireBus(((LSM303DLHCDriver *)ip)->config->i2cp);
i2cStart(((LSM303DLHCDriver *)ip)->config->i2cp,
((LSM303DLHCDriver *)ip)->config->i2ccfg);
#endif /* LSM303DLHC_SHARED_I2C */
msg = lsm303dlhcI2CReadRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_ACC, LSM303DLHC_AD_ACC_OUT_X_L,
buff, LSM303DLHC_ACC_NUMBER_OF_AXES * 2);
if(msg == MSG_OK)
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++) {
tmp = buff[2*i] + (buff[2*i+1] << 8);
axes[i] = (int32_t)tmp;
}
#if LSM303DLHC_SHARED_I2C
i2cReleaseBus(((LSM303DLHCDriver *)ip)->config->i2cp);
#endif /* LSM303DLHC_SHARED_I2C */
return msg;
}
static msg_t comp_read_raw(void *ip, int32_t axes[]) {
uint8_t buff [LSM303DLHC_COMP_NUMBER_OF_AXES * 2], i;
int16_t tmp;
msg_t msg;
osalDbgCheck(((ip != NULL) && (axes != NULL)) &&
(((LSM303DLHCDriver *)ip)->config->compcfg != NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"comp_read_raw(), invalid state");
osalDbgAssert((((LSM303DLHCDriver *)ip)->config->i2cp->state == I2C_READY),
"comp_read_raw(), channel not ready");
#if LSM303DLHC_SHARED_I2C
i2cAcquireBus(((LSM303DLHCDriver *)ip)->config->i2cp);
i2cStart(((LSM303DLHCDriver *)ip)->config->i2cp,
((LSM303DLHCDriver *)ip)->config->i2ccfg);
#endif /* LSM303DLHC_SHARED_I2C */
msg = lsm303dlhcI2CReadRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_COMP, LSM303DLHC_AD_COMP_OUT_X_L,
buff, LSM303DLHC_COMP_NUMBER_OF_AXES * 2);
if(msg == MSG_OK)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
tmp = buff[2*i] + (buff[2*i+1] << 8);
axes[i] = (int32_t)tmp;
}
#if LSM303DLHC_SHARED_I2C
i2cReleaseBus(((LSM303DLHCDriver *)ip)->config->i2cp);
#endif /* LSM303DLHC_SHARED_I2C */
return MSG_OK;
}
static msg_t sens_read_raw(void *ip, int32_t axes[]) {
int32_t* bp = axes;
msg_t msg;
if (((LSM303DLHCDriver *)ip)->config->acccfg != NULL) {
msg = acc_read_raw(ip, bp);
if(msg != MSG_OK)
return msg;
bp += LSM303DLHC_ACC_NUMBER_OF_AXES;
}
if (((LSM303DLHCDriver *)ip)->config->compcfg != NULL) {
msg = comp_read_raw(ip, bp);
}
return msg;
}
static msg_t acc_read_cooked(void *ip, float axes[]) {
uint32_t i;
int32_t raw[LSM303DLHC_ACC_NUMBER_OF_AXES];
msg_t msg;
osalDbgCheck(((ip != NULL) && (axes != NULL)) &&
(((LSM303DLHCDriver *)ip)->config->acccfg != NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"acc_read_cooked(), invalid state");
msg = acc_read_raw(ip, raw);
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES ; i++){
axes[i] = raw[i] * ((LSM303DLHCDriver *)ip)->accsensitivity[i];
axes[i] -= ((LSM303DLHCDriver *)ip)->accbias[i];
}
return msg;
}
static msg_t comp_read_cooked(void *ip, float axes[]) {
uint32_t i;
int32_t raw[LSM303DLHC_COMP_NUMBER_OF_AXES];
msg_t msg;
osalDbgCheck(((ip != NULL) && (axes != NULL)) &&
(((LSM303DLHCDriver *)ip)->config->compcfg != NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"comp_read_cooked(), invalid state");
msg = comp_read_raw(ip, raw);
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES ; i++){
axes[i] = raw[i] * ((LSM303DLHCDriver *)ip)->compsensitivity[i];
axes[i] -= ((LSM303DLHCDriver *)ip)->compbias[i];
}
return msg;
}
static msg_t sens_read_cooked(void *ip, float axes[]) {
float* bp = axes;
msg_t msg;
if (((LSM303DLHCDriver *)ip)->config->acccfg != NULL) {
msg = acc_read_cooked(ip, bp);
if(msg != MSG_OK)
return msg;
bp += LSM303DLHC_ACC_NUMBER_OF_AXES;
}
if (((LSM303DLHCDriver *)ip)->config->compcfg != NULL) {
msg = comp_read_cooked(ip, bp);
}
return msg;
}
static msg_t acc_set_bias(void *ip, int32_t *bp) {
uint32_t i;
osalDbgCheck((ip != NULL) && (bp !=NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY) ||
(((LSM303DLHCDriver *)ip)->state == LSM303DLHC_STOP),
"acc_set_bias(), invalid state");
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->accbias[i] = bp[i];
}
return MSG_OK;
}
static msg_t comp_set_bias(void *ip, int32_t *bp) {
uint32_t i;
osalDbgCheck((ip != NULL) && (bp !=NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY) ||
(((LSM303DLHCDriver *)ip)->state == LSM303DLHC_STOP),
"comp_set_bias(), invalid state");
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->compbias[i] = bp[i];
}
return MSG_OK;
}
static msg_t acc_reset_bias(void *ip) {
uint32_t i;
osalDbgCheck(ip != NULL);
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY) ||
(((LSM303DLHCDriver *)ip)->state == LSM303DLHC_STOP),
"acc_reset_bias(), invalid state");
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->accbias[i] = 0;
return MSG_OK;
}
static msg_t comp_reset_bias(void *ip) {
uint32_t i;
osalDbgCheck(ip != NULL);
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY) ||
(((LSM303DLHCDriver *)ip)->state == LSM303DLHC_STOP),
"comp_reset_bias(), invalid state");
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->compbias[i] = 0;
return MSG_OK;
}
static msg_t acc_set_sensivity(void *ip, float *sp) {
uint32_t i;
osalDbgCheck((ip != NULL) && (sp !=NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"acc_set_sensivity(), invalid state");
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->accsensitivity[i] = sp[i];
}
return MSG_OK;
}
static msg_t comp_set_sensivity(void *ip, float *sp) {
uint32_t i;
osalDbgCheck((ip != NULL) && (sp !=NULL));
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"comp_set_sensivity(), invalid state");
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = sp[i];
}
return MSG_OK;
}
static msg_t acc_reset_sensivity(void *ip) {
uint32_t i;
osalDbgCheck(ip != NULL);
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"acc_reset_sensivity(), invalid state");
if(((LSM303DLHCDriver *)ip)->config->acccfg->fullscale == LSM303DLHC_ACC_FS_2G)
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->accsensitivity[i] = LSM303DLHC_ACC_SENS_2G;
else if(((LSM303DLHCDriver *)ip)->config->acccfg->fullscale == LSM303DLHC_ACC_FS_4G)
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->accsensitivity[i] = LSM303DLHC_ACC_SENS_4G;
else if(((LSM303DLHCDriver *)ip)->config->acccfg->fullscale == LSM303DLHC_ACC_FS_8G)
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->accsensitivity[i] = LSM303DLHC_ACC_SENS_8G;
else if(((LSM303DLHCDriver *)ip)->config->acccfg->fullscale == LSM303DLHC_ACC_FS_16G)
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
((LSM303DLHCDriver *)ip)->accsensitivity[i] = LSM303DLHC_ACC_SENS_16G;
else {
osalDbgAssert(FALSE, "reset_sensivity(), accelerometer full scale issue");
return MSG_RESET;
}
return MSG_OK;
}
static msg_t comp_reset_sensivity(void *ip) {
uint32_t i;
osalDbgCheck(ip != NULL);
osalDbgAssert((((LSM303DLHCDriver *)ip)->state == LSM303DLHC_READY),
"comp_reset_sensivity(), invalid state");
if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_1P3GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_1P3GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_1P3GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_1P9GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_1P9GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_1P9GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_2P5GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_2P5GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_2P5GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_4P0GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_4P0GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_4P0GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_4P7GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_4P7GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_4P7GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_5P6GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_5P6GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_5P6GA;
}
}
else if(((LSM303DLHCDriver *)ip)->config->compcfg->fullscale == LSM303DLHC_COMP_FS_8P1GA)
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_8P1GA;
}
else {
((LSM303DLHCDriver *)ip)->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_8P1GA;
}
}
else {
osalDbgAssert(FALSE, "reset_sensivity(), compass full scale issue");
return MSG_RESET;
}
return MSG_OK;
}
static msg_t acc_set_full_scale(void *ip, lsm303dlhc_acc_fs_t fs) {
float newfs, scale;
uint8_t i, buff[2];
msg_t msg;
if(fs == LSM303DLHC_ACC_FS_2G) {
newfs = LSM303DLHC_ACC_2G;
}
else if(fs == LSM303DLHC_ACC_FS_4G) {
newfs = LSM303DLHC_ACC_4G;
}
else if(fs == LSM303DLHC_ACC_FS_8G) {
newfs = LSM303DLHC_ACC_8G;
}
else if(fs == LSM303DLHC_ACC_FS_16G) {
newfs = LSM303DLHC_ACC_16G;
}
else {
return MSG_RESET;
}
if(newfs != ((LSM303DLHCDriver *)ip)->accfullscale) {
scale = newfs / ((LSM303DLHCDriver *)ip)->accfullscale;
((LSM303DLHCDriver *)ip)->accfullscale = newfs;
/* Updating register.*/
msg = lsm303dlhcI2CReadRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_ACC,
LSM303DLHC_AD_ACC_CTRL_REG4,
&buff[1], 1);
if(msg != MSG_OK)
return msg;
buff[1] &= ~(LSM303DLHC_CTRL_REG4_A_FS_MASK);
buff[1] |= fs;
buff[0] = LSM303DLHC_AD_ACC_CTRL_REG4;
msg = lsm303dlhcI2CWriteRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_ACC, buff, 1);
if(msg != MSG_OK)
return msg;
/* Scaling sensitivity and bias. Re-calibration is suggested anyway. */
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->accsensitivity[i] *= scale;
((LSM303DLHCDriver *)ip)->accbias[i] *= scale;
}
}
return msg;
}
static msg_t comp_set_full_scale(void *ip, lsm303dlhc_comp_fs_t fs) {
float newfs, scale;
uint8_t i, buff[2];
msg_t msg;
if(fs == LSM303DLHC_COMP_FS_1P3GA) {
newfs = LSM303DLHC_COMP_1P3GA;
}
else if(fs == LSM303DLHC_COMP_FS_1P9GA) {
newfs = LSM303DLHC_COMP_1P9GA;
}
else if(fs == LSM303DLHC_COMP_FS_2P5GA) {
newfs = LSM303DLHC_COMP_2P5GA;
}
else if(fs == LSM303DLHC_COMP_FS_4P0GA) {
newfs = LSM303DLHC_COMP_4P0GA;
}
else if(fs == LSM303DLHC_COMP_FS_4P7GA) {
newfs = LSM303DLHC_COMP_4P7GA;
}
else if(fs == LSM303DLHC_COMP_FS_5P6GA) {
newfs = LSM303DLHC_COMP_5P6GA;
}
else if(fs == LSM303DLHC_COMP_FS_8P1GA) {
newfs = LSM303DLHC_COMP_8P1GA;
}
else {
return MSG_RESET;
}
if(newfs != ((LSM303DLHCDriver *)ip)->compfullscale) {
scale = newfs / ((LSM303DLHCDriver *)ip)->compfullscale;
((LSM303DLHCDriver *)ip)->compfullscale = newfs;
/* Updating register.*/
msg = lsm303dlhcI2CReadRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_COMP,
LSM303DLHC_AD_COMP_CRB_REG,
&buff[1], 1);
if(msg != MSG_OK)
return msg;
buff[1] &= ~(LSM303DLHC_CRB_REG_M_GN_MASK);
buff[1] |= fs;
buff[0] = LSM303DLHC_AD_COMP_CRB_REG;
msg = lsm303dlhcI2CWriteRegister(((LSM303DLHCDriver *)ip)->config->i2cp,
LSM303DLHC_SAD_COMP, buff, 1);
if(msg != MSG_OK)
return msg;
/* Scaling sensitivity and bias. Re-calibration is suggested anyway. */
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
((LSM303DLHCDriver *)ip)->compsensitivity[i] *= scale;
((LSM303DLHCDriver *)ip)->compbias[i] *= scale;
}
}
return MSG_OK;
}
static const struct BaseSensorVMT vmt_basesensor = {
sens_get_axes_number, sens_read_raw, sens_read_cooked
};
static const struct BaseCompassVMT vmt_basecompass = {
comp_get_axes_number, comp_read_raw, comp_read_cooked,
comp_set_bias, comp_reset_bias, comp_set_sensivity, comp_reset_sensivity
};
static const struct BaseAccelerometerVMT vmt_baseaccelerometer = {
acc_get_axes_number, acc_read_raw, acc_read_cooked,
acc_set_bias, acc_reset_bias, acc_set_sensivity, acc_reset_sensivity
};
static const struct LSM303DLHCACCVMT vmt_lsm303dlhcacc = {
acc_get_axes_number, acc_read_raw, acc_read_cooked,
acc_set_bias, acc_reset_bias, acc_set_sensivity, acc_reset_sensivity,
acc_set_full_scale
};
static const struct LSM303DLHCCOMPVMT vmt_lsm303dlhccomp = {
comp_get_axes_number, comp_read_raw, comp_read_cooked,
comp_set_bias, comp_reset_bias, comp_set_sensivity, comp_reset_sensivity,
comp_set_full_scale
};
/*===========================================================================*/
/* Driver exported functions. */
/*===========================================================================*/
/**
* @brief Initializes an instance.
*
* @param[out] devp pointer to the @p LSM303DLHCDriver object
*
* @init
*/
void lsm303dlhcObjectInit(LSM303DLHCDriver *devp) {
uint32_t i;
devp->vmt_basesensor = &vmt_basesensor;
devp->vmt_baseaccelerometer = &vmt_baseaccelerometer;
devp->vmt_basecompass = &vmt_basecompass;
devp->vmt_lsm303dlhcacc = &vmt_lsm303dlhcacc;
devp->vmt_lsm303dlhccomp = &vmt_lsm303dlhccomp;
devp->config = NULL;
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
devp->accbias[i] = 0;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++)
devp->compbias[i] = 0;
devp->state = LSM303DLHC_STOP;
}
/**
* @brief Configures and activates LSM303DLHC Complex Driver peripheral.
*
* @param[in] devp pointer to the @p LSM303DLHCDriver object
* @param[in] config pointer to the @p LSM303DLHCConfig object
*
* @api
*/
void lsm303dlhcStart(LSM303DLHCDriver *devp, const LSM303DLHCConfig *config) {
uint32_t i;
uint8_t buff[6] = {0, 0, 0, 0, 0, 0};
osalDbgCheck((devp != NULL) && (config != NULL));
osalDbgAssert((devp->state == LSM303DLHC_STOP) || (devp->state == LSM303DLHC_READY),
"lsm303dlhcStart(), invalid state");
devp->config = config;
#if LSM303DLHC_SHARED_I2C
i2cAcquireBus((devp)->config->i2cp);
#endif /* LSM303DLHC_SHARED_I2C */
i2cStart((devp)->config->i2cp,
(devp)->config->i2ccfg);
if((devp)->config->acccfg != NULL) {
/* Multiple write starting address.*/
buff[0] = LSM303DLHC_AD_ACC_CTRL_REG1;
/* Control register 1 configuration block.*/
{
buff[1] = LSM303DLHC_CTRL_REG1_A_XEN | LSM303DLHC_CTRL_REG1_A_YEN |
LSM303DLHC_CTRL_REG1_A_ZEN | devp->config->acccfg->outdatarate;
#if LSM303DLHC_ACC_USE_ADVANCED || defined(__DOXYGEN__)
buff[1] |= devp->config->acccfg->lowpower;
#endif
}
/* Control register 2 configuration block.*/
{
buff[2] = 0;
}
/* Control register 3 configuration block.*/
{
buff[3] = 0;
}
/* Control register 4 configuration block.*/
{
buff[4] = devp->config->acccfg->fullscale;
#if LSM303DLHC_ACC_USE_ADVANCED || defined(__DOXYGEN__)
buff[4] |= devp->config->acccfg->endianess |
devp->config->acccfg->blockdataupdate |
devp->config->acccfg->highresmode;
#endif
}
lsm303dlhcI2CWriteRegister(devp->config->i2cp, LSM303DLHC_SAD_ACC,
buff, 4);
}
if((devp)->config->compcfg != NULL) {
/* Multiple write starting address.*/
buff[0] = LSM303DLHC_AD_COMP_CRA_REG;
/* Control register A configuration block.*/
{
buff[1] = devp->config->compcfg->outputdatarate;
}
/* Control register B configuration block.*/
{
buff[2] = devp->config->compcfg->fullscale;
}
/* Mode register configuration block.*/
{
buff[3] = 0;
#if LSM303DLHC_COMP_USE_ADVANCED || defined(__DOXYGEN__)
buff[3] |= devp->config->compcfg->mode;
#endif
}
lsm303dlhcI2CWriteRegister(devp->config->i2cp, LSM303DLHC_SAD_COMP,
buff, 3);
}
#if LSM303DLHC_SHARED_I2C
i2cReleaseBus((devp)->config->i2cp);
#endif /* LSM303DLHC_SHARED_I2C */
/* Storing sensitivity information according to full scale value */
if((devp)->config->acccfg != NULL) {
if(devp->config->acccfg->fullscale == LSM303DLHC_ACC_FS_2G) {
devp->accfullscale = LSM303DLHC_ACC_2G;
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
devp->accsensitivity[i] = LSM303DLHC_ACC_SENS_2G;
}
else if(devp->config->acccfg->fullscale == LSM303DLHC_ACC_FS_4G) {
devp->accfullscale = LSM303DLHC_ACC_4G;
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
devp->accsensitivity[i] = LSM303DLHC_ACC_SENS_4G;
}
else if(devp->config->acccfg->fullscale == LSM303DLHC_ACC_FS_8G) {
devp->accfullscale = LSM303DLHC_ACC_8G;
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
devp->accsensitivity[i] = LSM303DLHC_ACC_SENS_8G;
}
else if(devp->config->acccfg->fullscale == LSM303DLHC_ACC_FS_16G) {
devp->accfullscale = LSM303DLHC_ACC_16G;
for(i = 0; i < LSM303DLHC_ACC_NUMBER_OF_AXES; i++)
devp->accsensitivity[i] = LSM303DLHC_ACC_SENS_16G;
}
else
osalDbgAssert(FALSE, "lsm303dlhcStart(), accelerometer full scale issue");
}
if((devp)->config->compcfg != NULL) {
if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_1P3GA) {
devp->compfullscale = LSM303DLHC_COMP_1P3GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_1P3GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_1P3GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_1P9GA) {
devp->compfullscale = LSM303DLHC_COMP_1P9GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_1P9GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_1P9GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_2P5GA) {
devp->compfullscale = LSM303DLHC_COMP_2P5GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_2P5GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_2P5GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_4P0GA) {
devp->compfullscale = LSM303DLHC_COMP_4P0GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_4P0GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_4P0GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_4P7GA) {
devp->compfullscale = LSM303DLHC_COMP_4P7GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_4P7GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_4P7GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_5P6GA) {
devp->compfullscale = LSM303DLHC_COMP_5P6GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_5P6GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_5P6GA;
}
}
}
else if(devp->config->compcfg->fullscale == LSM303DLHC_COMP_FS_8P1GA) {
devp->compfullscale = LSM303DLHC_COMP_8P1GA;
for(i = 0; i < LSM303DLHC_COMP_NUMBER_OF_AXES; i++) {
if(i != 2) {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_XY_8P1GA;
}
else {
devp->compsensitivity[i] = LSM303DLHC_COMP_SENS_Z_8P1GA;
}
}
}
else
osalDbgAssert(FALSE, "lsm303dlhcStart(), compass full scale issue");
}
/* This is the Compass transient recovery time */
osalThreadSleepMilliseconds(5);
devp->state = LSM303DLHC_READY;
}
/**
* @brief Deactivates the LSM303DLHC Complex Driver peripheral.
*
* @param[in] devp pointer to the @p LSM303DLHCDriver object
*
* @api
*/
void lsm303dlhcStop(LSM303DLHCDriver *devp) {
uint8_t buff[2];
osalDbgCheck(devp != NULL);
osalDbgAssert((devp->state == LSM303DLHC_STOP) || (devp->state == LSM303DLHC_READY),
"lsm303dlhcStop(), invalid state");
if (devp->state == LSM303DLHC_STOP) {
#if LSM303DLHC_SHARED_I2C
i2cAcquireBus((devp)->config->i2cp);
i2cStart((devp)->config->i2cp,
(devp)->config->i2ccfg);
#endif /* LSM303DLHC_SHARED_I2C */
if((devp)->config->acccfg != NULL) {
buff[0] = LSM303DLHC_AD_ACC_CTRL_REG1;
buff[1] = LSM303DLHC_ACC_AE_DISABLED | LSM303DLHC_ACC_ODR_PD;
lsm303dlhcI2CWriteRegister(devp->config->i2cp, LSM303DLHC_SAD_ACC,
buff, 1);
}
if((devp)->config->compcfg != NULL) {
buff[0] = LSM303DLHC_AD_COMP_MR_REG;
buff[1] = LSM303DLHC_COMP_MD_SLEEP;
lsm303dlhcI2CWriteRegister(devp->config->i2cp, LSM303DLHC_SAD_ACC,
buff, 1);
lsm303dlhcI2CWriteRegister(devp->config->i2cp, LSM303DLHC_SAD_COMP,
buff, 1);
}
i2cStop((devp)->config->i2cp);
#if LSM303DLHC_SHARED_I2C
i2cReleaseBus((devp)->config->i2cp);
#endif /* LSM303DLHC_SHARED_I2C */
}
devp->state = LSM303DLHC_STOP;
}
/** @} */