/*
* Driver for 3-axis digital compass HMC5883L
*
* Part of esp-open-rtos
* Copyright (C) 2016 Ruslan V. Uss <unclerus@gmail.com>
* BSD Licensed as described in the file LICENSE
*/
#include "hmc5883l.h"
#include <i2c/i2c.h>
#include <espressif/esp_common.h>
#define ADDR 0x1e
#define REG_CR_A 0x00
#define REG_CR_B 0x01
#define REG_MODE 0x02
#define REG_DX_H 0x03
#define REG_DX_L 0x04
#define REG_DZ_H 0x05
#define REG_DZ_L 0x06
#define REG_DY_H 0x07
#define REG_DY_L 0x08
#define REG_STAT 0x09
#define REG_ID_A 0x0a
#define REG_ID_B 0x0b
#define REG_ID_C 0x0c
#define BIT_MA 5
#define BIT_DO 2
#define BIT_GN 5
#define MASK_MD 0x03
#define MASK_MA 0x60
#define MASK_DO 0x1c
#define MASK_MS 0x03
#define MASK_DR 0x01
#define MASK_DL 0x02
#define MEASUREMENT_TIMEOUT 6000
static const float gain_values [] = {
[HMC5883L_GAIN_1370] = 0.73,
[HMC5883L_GAIN_1090] = 0.92,
[HMC5883L_GAIN_820] = 1.22,
[HMC5883L_GAIN_660] = 1.52,
[HMC5883L_GAIN_440] = 2.27,
[HMC5883L_GAIN_390] = 2.56,
[HMC5883L_GAIN_330] = 3.03,
[HMC5883L_GAIN_230] = 4.35
};
static float current_gain;
static hmc5883l_operating_mode_t current_mode;
static inline void write_register(uint8_t reg, uint8_t val)
{
uint8_t buf[2] = { reg, val };
i2c_slave_write(ADDR, buf, 2);
}
static inline uint8_t read_register(uint8_t reg)
{
uint8_t res;
i2c_slave_read(ADDR, reg, &res, 1);
return res;
}
static inline void update_register(uint8_t reg, uint8_t mask, uint8_t val)
{
write_register(reg, (read_register(reg) & mask) | val);
}
bool hmc5883l_init()
{
if (hmc5883l_get_id() != HMC5883L_ID)
return false;
current_gain = gain_values[hmc5883l_get_gain()];
current_mode = hmc5883l_get_operating_mode();
return true;
}
uint32_t hmc5883l_get_id()
{
uint32_t res = 0;
i2c_slave_read(ADDR, REG_ID_A, (uint8_t *)&res, 3);
return res;
}
hmc5883l_operating_mode_t hmc5883l_get_operating_mode()
{
uint8_t res = read_register(REG_MODE) & MASK_MD;
return res == 0 ? HMC5883L_MODE_CONTINUOUS : HMC5883L_MODE_SINGLE;
}
void hmc5883l_set_operating_mode(hmc5883l_operating_mode_t mode)
{
write_register(REG_MODE, mode);
current_mode = mode;
}
hmc5883l_samples_averaged_t hmc5883l_get_samples_averaged()
{
return (read_register(REG_CR_A) & MASK_MA) >> BIT_MA;
}
void hmc5883l_set_samples_averaged(hmc5883l_samples_averaged_t samples)
{
update_register(REG_CR_A, MASK_MA, samples << BIT_MA);
}
hmc5883l_data_rate_t hmc5883l_get_data_rate()
{
return (read_register(REG_CR_A) & MASK_DO) >> BIT_DO;
}
void hmc5883l_set_data_rate(hmc5883l_data_rate_t rate)
{
update_register(REG_CR_A, MASK_DO, rate << BIT_DO);
}
hmc5883l_bias_t hmc5883l_get_bias()
{
return read_register(REG_CR_A) & MASK_MS;
}
void hmc5883l_set_bias(hmc5883l_bias_t bias)
{
update_register(REG_CR_A, MASK_MS, bias);
}
hmc5883l_gain_t hmc5883l_get_gain()
{
return read_register(REG_CR_B) >> BIT_GN;
}
void hmc5883l_set_gain(hmc5883l_gain_t gain)
{
write_register(REG_CR_B, gain << BIT_GN);
current_gain = gain_values[gain];
}
bool hmc5883l_data_is_locked()
{
return read_register(REG_STAT) & MASK_DL;
}
bool hmc5883l_data_is_ready()
{
return read_register(REG_STAT) & MASK_DR;
}
bool hmc5883l_get_raw_data(hmc5883l_raw_data_t *data)
{
if (current_mode == HMC5883L_MODE_SINGLE)
{
// overwrite mode register for measurement
hmc5883l_set_operating_mode(current_mode);
// wait for data
uint32_t timeout = sdk_system_get_time() + MEASUREMENT_TIMEOUT;
while (!hmc5883l_data_is_ready())
{
if (sdk_system_get_time() >= timeout)
return false;
}
}
uint8_t buf[6];
i2c_slave_read(ADDR, REG_DX_H, buf, 6);
data->x = ((int16_t)buf[REG_DX_H - REG_DX_H] << 8) | buf[REG_DX_L - REG_DX_H];
data->y = ((int16_t)buf[REG_DY_H - REG_DX_H] << 8) | buf[REG_DY_L - REG_DX_H];
data->z = ((int16_t)buf[REG_DZ_H - REG_DX_H] << 8) | buf[REG_DZ_L - REG_DX_H];
return true;
}
void hmc5883l_raw_to_mg(const hmc5883l_raw_data_t *raw, hmc5883l_data_t *mg)
{
mg->x = raw->x * current_gain;
mg->y = raw->y * current_gain;
mg->z = raw->z * current_gain;
}
bool hmc5883l_get_data(hmc5883l_data_t *data)
{
hmc5883l_raw_data_t raw;
if (!hmc5883l_get_raw_data(&raw))
return false;
hmc5883l_raw_to_mg(&raw, data);
return true;
}