Arun Raj
TEST
Dependencies: max32630fthr Adafruit_FeatherOLED USBDevice
Interfaces/SmartSensor/SSInterface.h
- Committer:
- gmehmet
- Date:
- 2019-04-10
- Revision:
- 1:f60eafbf009a
File content as of revision 1:f60eafbf009a:
/***************************************************************************
* Copyright (C) 2017 Maxim Integrated Products, Inc., All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES
* OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*
* Except as contained in this notice, the name of Maxim Integrated
* Products, Inc. shall not be used except as stated in the Maxim Integrated
* Products, Inc. Branding Policy.
*
* The mere transfer of this software does not imply any licenses
* of trade secrets, proprietary technology, copyrights, patents,
* trademarks, maskwork rights, or any other form of intellectual
* property whatsoever. Maxim Integrated Products, Inc. retains all
* ownership rights.
****************************************************************************
*/
#ifndef _SSINTERFACE_H_
#define _SSINTERFACE_H_
#include "mbed.h"
#include "MaximSensor.h"
#include "EventStats.h"
#define SS_PLATFORM_MAX3263X "SmartSensor_MAX3263X"
#define SS_PLATFORM_MAX32660 "SmartSensor_MAX32660"
#define SS_BOOTLOADER_PLATFORM_MAX3263X "Bootloader_MAX3263X"
#define SS_BOOTLOADER_PLATFORM_MAX32660 "Bootloader_MAX32660"
#define SS_I2C_8BIT_SLAVE_ADDR 0xAA
#define SS_DEFAULT_CMD_SLEEP_MS 2
#define SS_DEFAULT2_CMD_SLEEP_MS 4
#define SS_DEFAULT3_CMD_SLEEP_MS 30
#define SS_DUMP_REG_SLEEP_MS 100
#define SS_ENABLE_SENSOR_SLEEP_MS 20
#define SH_INPUT_DATA_DIRECT_SENSOR 0x00 // Default
#define SH_INPUT_DATA_FROM_HOST 0x01
#define SS_SENSORIDX_MAX86140 0x00
#define SS_SENSORIDX_MAX30205 0x01
#define SS_SENSORIDX_MAX30001 0x02
#define SS_SENSORIDX_MAX30101 0x03
#define SS_SENSORIDX_ACCEL 0x04
#define SS_ALGOIDX_AGC 0x00
#define SS_ALGOIDX_AEC 0x01
#define SS_ALGOIDX_WHRM 0x02
#define SS_ALGOIDX_ECG 0x03
#define SS_ALGOIDX_BPT 0x04
#define SS_ALGOIDX_WSPO2 0x05 /// additional index
#define SS_FAM_R_STATUS 0x00
#define SS_CMDIDX_STATUS 0x00
#define SS_SHIFT_STATUS_ERR 0
#define SS_MASK_STATUS_ERR (0x07 << SS_SHIFT_STATUS_ERR)
#define SS_SHIFT_STATUS_DATA_RDY 3
#define SS_MASK_STATUS_DATA_RDY (1 << SS_SHIFT_STATUS_DATA_RDY)
#define SS_SHIFT_STATUS_FIFO_OUT_OVR 4
#define SS_MASK_STATUS_FIFO_OUT_OVR (1 << SS_SHIFT_STATUS_FIFO_OUT_OVR)
#define SS_SHIFT_STATUS_FIFO_IN_OVR 5
#define SS_MASK_STATUS_FIFO_IN_OVR (1 << SS_SHIFT_STATUS_FIFO_IN_OVR)
#define SS_SHIFT_STATUS_LOG_OVR 6
#define SS_MASK_STATUS_LOG_OVR (1 << SS_SHIFT_STATUS_LOG_OVR)
#define SS_SHIFT_STATUS_LOG_RDY 7
#define SS_MASK_STATUS_LOG_RDY (1 << SS_SHIFT_STATUS_LOG_RDY)
#define SS_FAM_W_MODE 0x01
#define SS_FAM_R_MODE 0x02
#define SS_CMDIDX_MODE 0x00
#define SS_SHIFT_MODE_SHDN 0
#define SS_MASK_MODE_SHDN (1 << SS_SHIFT_MODE_SHDN)
#define SS_SHIFT_MODE_RESET 1
#define SS_MASK_MODE_RESET (1 << SS_SHIFT_MODE_RESET)
#define SS_SHIFT_MODE_FIFORESET 2
#define SS_MASK_MODE_FIFORESET (1 << SS_SHIFT_MODE_FIFORESET)
#define SS_SHIFT_MODE_BOOTLDR 3
#define SS_MASK_MODE_BOOTLDR (1 << SS_SHIFT_MODE_BOOTLDR)
#define SS_I2C_READ 0x03
#define SS_FAM_W_COMMCHAN 0x10
#define SS_FAM_R_COMMCHAN 0x11
#define SS_CMDIDX_OUTPUTMODE 0x00
#define SS_SHIFT_OUTPUTMODE_DATATYPE 0
#define SS_MASK_OUTPUTMODE_DATATYPE (0x03 << SS_SHIFT_OUTPUTMODE_DATATYPE)
#define SS_DATATYPE_PAUSE 0
#define SS_DATATYPE_RAW 1
#define SS_DATATYPE_ALGO 2
#define SS_DATATYPE_BOTH 3
#define SS_SHIFT_OUTPUTMODE_SC_EN 2
#define SS_MASK_OUTPUTMODE_SC_EN (1 << SS_SHIFT_OUTPUTMODE_SC_EN)
#define SS_CMDIDX_FIFOAFULL 0x01
#define SS_FAM_R_OUTPUTFIFO 0x12
#define SS_CMDIDX_OUT_NUMSAMPLES 0x00
#define SS_CMDIDX_READFIFO 0x01
#define SS_FAM_R_INPUTFIFO 0x13
#define SS_CMDIDX_SAMPLE_SIZE 0x00
#define SS_CMDIDX_INPUT_FIFO_SIZE 0x01
#define SS_CMDIDX_SENSOR_FIFO_SIZE 0x02
#define SS_CMDIDX_NUM_SAMPLES_SENSOR_FIFO 0x03
#define SS_CMDIDX_NUM_SAMPLES_INPUT_FIFO 0x04
#define SS_FAM_W_INPUTFIFO 0x14
#define SS_CMDIDX_WRITE_FIFO 0x00
#define SS_FAM_W_WRITEREG 0x40
#define SS_FAM_R_READREG 0x41
#define SS_FAM_R_REGATTRIBS 0x42
#define SS_FAM_R_DUMPREG 0x43
#define SS_FAM_W_SENSORMODE 0x44
#define SS_FAM_R_SENSORMODE 0x45
#define SS_FAM_W_ALGOCONFIG 0x50
#define SS_FAM_R_ALGOCONFIG 0x51
#define SS_CFGIDX_AGC_TARGET 0x00
#define SS_CFGIDX_AGC_CORR_COEFF 0x01
#define SS_CFGIDX_AGC_SENSITIVITY 0x02
#define SS_CFGIDX_AGC_SMP_AVG 0x03
#define SS_CFGIDX_WHRM_SR 0x00
#define SS_CFGIDX_WHRM_MAX_HEIGHT 0x01
#define SS_CFGIDX_WHRM_MAX_WEIGHT 0x02
#define SS_CFGIDX_WHRM_MAX_AGE 0x03
#define SS_CFGIDX_WHRM_MIN_HEIGHT 0x04
#define SS_CFGIDX_WHRM_MIN_WEIGHT 0x05
#define SS_CFGIDX_WHRM_MIN_AGE 0x06
#define SS_CFGIDX_WHRM_DEF_HEIGHT 0x07
#define SS_CFGIDX_WHRM_DEF_WEIGHT 0x08
#define SS_CFGIDX_WHRM_DEF_AGE 0x09
#define SS_CFGIDX_WHRM_INIT_HR 0x0A
// additional for WHRM_AEC_SCD
#define SS_CFGIDX_WHRM_AEC_ENABLE 0x0B
#define SS_CFGIDX_WHRM_SCD_ENABLE 0x0C
#define SS_CFGIDX_WHRM_ADJ_TARGET_PD_CURRENT_PERIOD 0x0D
#define SS_CFGIDX_WHRM_SCD_DEBOUNCE_WINDOW 0x0E
#define SS_CFGIDX_WHRM_MOTION_MAG_THRESHOLD 0x0F
#define SS_CFGIDX_WHRM_MIN_PD_CURRENT 0x10
#define SS_CFGIDX_WHRM_PD_CONFIG 0x11
#define SS_CFGIDX_WHRM_LED_CONFIG 0x12
// config for WSPO2
#define SS_CFGIDX_WSPO2_CAL 0x00
#define SS_CFGIDX_WSPO2_SR 0x01
#define SS_CFGIDX_WSPO2_ALGO_MODE 0x02
#define SS_CFGIDX_WSPO2_AGC_MODE 0x03
#define SS_CFGIDX_WSPO2_MOTION_DET 0x04
#define SS_CFGIDX_WSPO2_MOTION_PERIOD 0x05
#define SS_CFGIDX_WSPO2_MOTION_THRESHOLD 0x06
#define SS_CFGIDX_WSPO2_AGC_TIMEOUT 0x07
#define SS_CFGIDX_WSPO2_TIMEOUT 0x08
#define SS_CFGIDX_WSPO2_PD_CONFIG 0x09
#define SS_CFGIDX_BP_USE_MED 0x00
#define SS_CFGIDX_BP_SYS_BP_CAL 0x01
#define SS_CFGIDX_BP_DIA_BP_CAL 0x02
#define SS_CFGIDX_BP_CAL_DATA 0x03
#define SS_CFGIDX_BP_EST_DATE 0x04
#define SS_CFGIDX_BP_EST_NONREST 0x05
#define SS_CFGIDX_BP_SPO2_COEFS 0x06
#define SS_FAM_W_ALGOMODE 0x52
#define SS_FAM_R_ALGOMODE 0x53
#define SS_FAM_W_EXTERNSENSORMODE 0x60
#define SS_W_EXT_SENSOR_MODE 0x00
#define SS_FAM_R_EXTERNSENSORMODE 0x61
#define SS_R_EXT_SENSOR_MODE 0x00
#define SS_FAM_R_SELFTEST 0x70
#define SS_FAM_W_BOOTLOADER 0x80
#define SS_CMDIDX_SETIV 0x00
#define SS_CMDIDX_SETAUTH 0x01
#define SS_CMDIDX_SETNUMPAGES 0x02
#define SS_CMDIDX_ERASE 0x03
#define SS_CMDIDX_SENDPAGE 0x04
#define SS_CMDIDX_ERASE_PAGE 0x05
#define SS_FAM_R_BOOTLOADER 0x81
#define SS_CMDIDX_BOOTFWVERSION 0x00
#define SS_CMDIDX_PAGESIZE 0x01
#define SS_FAM_W_BOOTLOADER_CFG 0x82
#define SS_FAM_R_BOOTLOADER_CFG 0x83
#define SS_CMDIDX_BL_SAVE 0x00
#define SS_CMDIDX_BL_ENTRY 0x01
#define SS_BL_CFG_ENTER_BL_MODE 0x00
#define SS_BL_CFG_EBL_PIN 0x01
#define SS_BL_CFG_EBL_POL 0x02
#define SS_CMDIDX_BL_EXIT 0x02
#define SS_BL_CFG_EXIT_BL_MODE 0x00
#define SS_BL_CFG_TIMEOUT 0x01
/* Enable logging/debugging */
#define SS_FAM_R_LOG 0x90
#define SS_CMDIDX_R_LOG_DATA 0x00
#define SS_CMDIDX_R_LOG_LEN 0x01
#define SS_CMDIDX_R_LOG_LEVEL 0x02
#define SS_LOG_DISABLE 0x00
#define SS_LOG_CRITICAL 0x01
#define SS_LOG_ERROR 0x02
#define SS_LOG_INFO 0x04
#define SS_LOG_DEBUG 0x08
#define SS_FAM_W_LOG_CFG 0x91
#define SS_CMDIDX_LOG_GET_LEVEL 0x00
#define SS_CMDIDX_LOG_SET_LEVEL 0x01
#define SS_FAM_R_IDENTITY 0xFF
#define SS_CMDIDX_PLATTYPE 0x00
#define SS_CMDIDX_PARTID 0x01
#define SS_CMDIDX_REVID 0x02
#define SS_CMDIDX_FWVERSION 0x03
#define SS_CMDIDX_AVAILSENSORS 0x04
#define SS_CMDIDX_DRIVERVER 0x05
#define SS_CMDIDX_AVAILALGOS 0x06
#define SS_CMDIDX_ALGOVER 0x07
typedef enum {
SS_SUCCESS=0x00,
SS_ERR_COMMAND=0x01,
SS_ERR_UNAVAILABLE=0x02,
SS_ERR_DATA_FORMAT=0x03,
SS_ERR_INPUT_VALUE=0x04,
SS_ERR_BTLDR_GENERAL=0x80,
SS_ERR_BTLDR_CHECKSUM=0x81,
SS_ERR_TRY_AGAIN=0xFE,
SS_ERR_UNKNOWN=0xFF,
} SS_STATUS;
typedef enum {
SS_PLAT_MAX3263X=0,
SS_PLAT_MAX32660=1,
} SS_PLAT_TYPE;
//self test result masks
#define FAILURE_COMM 0x01
#define FAILURE_INTERRUPT 0x02
#define SS_SMALL_BUF_SIZE 32
#define SS_MED_BUF_SIZE 512
#define SS_LARGE_BUF_SIZE 8224
#define SS_RESET_TIME 10
#define SS_STARTUP_TO_BTLDR_TIME 50
#define SS_STARTUP_TO_MAIN_APP_TIME 1000
#define SS_MAX_SUPPORTED_SENSOR_NUM 0xFE
#define SS_MAX_SUPPORTED_ALGO_NUM 0xFE
#define SS_MAX_SUPPORTED_ALGO_CFG_NUM 0xFE
#define SS_MAX_SUPPORTED_MODE_NUM 0xFF
/* BOOTLOADER HOST */
#define EBL_CMD_TRIGGER_MODE 0
#define EBL_GPIO_TRIGGER_MODE 1
typedef struct {
int data_size;
Callback<void(uint8_t*)> callback;
} ss_data_req;
typedef union {
struct {
uint16_t whrm_enabled :1;
uint16_t wspo2_enabled :1; /// added
uint16_t bpt_enabled :1;
uint16_t agc_enabled :1;
uint16_t max8614x_enabled:1;
uint16_t max3010x_enabled:1;
uint16_t accel_enabled :1;
uint16_t sensorhub_accel :1; // added to specify if sensor hub accel is used or host (default)
uint16_t placeholder :8; //
};
uint16_t status_vals;
} status_algo_sensors_st;
/**
* @brief SSInterface is Maxim's SmartSensor Interface class
*/
class SSInterface
{
public:
/* PUBLIC FUNCTION DECLARATIONS */
/**
* @brief SSInterface constructor.
*
* @param[in] i2cBus - reference to the I2C bus for the SmartSensor
* @param[in] ss_mfio - name of SmartSensor multi-function IO pin
* @param[in] ss_reset - name of SmartSensor Reset pin
*
*/
SSInterface(I2C &i2cBus, PinName ss_mfio, PinName ss_reset);
/**
* @brief SSInterface constructor.
*
* @param[in] spiBus - reference to the SPI bus for the SmartSensor
* @param[in] ss_mfio - name of SmartSensor multi-function IO pin
* @param[in] ss_reset - name of SmartSensor Reset pin
*
*/
SSInterface(SPI &spiBus, PinName ss_mfio, PinName ss_reset);
/**
* @brief DSInterface destructor.
*
*/
~SSInterface();
/**
* @brief Write a command to the SmartSensor and get status response
*
* @param[in] cmd_bytes - Pointer to the command's family and index bytes
* @param[in] cmd_idx_len - The number of bytes in the command
* @param[in] data - Pointer to the command's data bytes
* @param[in] data_len - The number data bytes
*
* @return SS_STATUS byte
*/
SS_STATUS write_cmd(uint8_t *cmd_bytes, int cmd_bytes_len,
uint8_t *data, int data_len,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
/**
* @brief Write a command to the SmartSensor and get status response
*
* @param[in] tx_buf - Pointer to the command's family, index bytes and data bytes
* @param[in] tx_len - Total transaction lenght to send
*
* @return SS_STATUS byte
*/
SS_STATUS write_cmd(uint8_t *tx_buf, int tx_len,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
/**
* @brief Write a command to the SmartSensor and get status response
*
* @param[in] cmd_bytes - Pointer to the command's family and index bytes
* @param[in] cmd_idx_len - The number of bytes in the command
* @param[in] data - Pointer to the command's data bytes
* @param[in] data_len - The number data bytes
* @param[in] rxbuf - Buffer to fill in with read data (including status byte)
* @param[in] rxbuf_sz - Size of the rx buffer (to prevent overflow)
*
* @return SS_STATUS byte
*/
SS_STATUS read_cmd( uint8_t *cmd_bytes, int cmd_bytes_len,
uint8_t *data, int data_len,
uint8_t *rxbuf, int rxbuf_sz,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
/**
* @brief Get a string representing the SmartSensor firmware version
* @details If in bootloader mode, returns bootloader version
*
* @return Pointer to firmware version string
*/
const char* get_ss_fw_version();
/**
* @brief Get a string representing the SmartSensor algo version
* @details If in bootloader mode, returns bootloader version
*
* @return Pointer to algo version string
*/
const char* get_ss_algo_version();
/**
* @brief Get a string representing the SmartSensor platform type
*
* @return Pointer to platform type string
*/
const char* get_ss_platform_name();
/**
* @brief Reset the SmartSensor and jump to main application
*
* @return SS_STATUS code indicating success
*/
SS_STATUS reset_to_main_app();
/**
* @brief Reset the SmartSensor and jump to bootloader
*
* @return SS_STATUS code indicating success
*/
SS_STATUS reset_to_bootloader();
/**
* @brief Reset the SmartSensor
* @details If the SmartSensor was in bootloader, it will jump back into bootloader
* If the SmartSensor was in main app, it will jump back into main app
*
* @return SS_STATUS code indicating success
*/
SS_STATUS reset();
/**
* @brief run the self test commands
* param[in] idx - the id of the sensor for the self test
* param[in] result - self-test response
* param[in] sleep_ms - duration of wait for read command
* @return SS_STATUS code indicating success
*/
SS_STATUS self_test(int idx, uint8_t *result, int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
/**
* @brief Check if SmartSensor is in bootloader mode
*
* @return 1 if in bootloader mode, 0 if in main app, -1 if comm error
*/
int in_bootldr_mode();
/**
* @brief Read register from a device onboard SmartSensor
*
* @param[in] idx - Index of device to read
* @param[in] addr - Register address
* @param[out] val - Register value
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_reg(int idx, uint8_t addr, uint32_t *val);
/**
* @brief Set register of a device onboard SmartSensor
*
* @param[in] idx - Index of device to read
* @param[in] addr - Register address
* @param[in] val - Register value
* @param[in] byte_size - Size of IC register in bytes
*
* @return SS_SUCCESS on success
*/
SS_STATUS set_reg(int idx, uint8_t addr, uint32_t val, int byte_size);
/**
* @brief Dump registers of a device onboard SmartSensor
*
* @param[in] idx - Index of device
* @param[in] reg_vals - Array of addr_val_pairs
* @param[in] reg_vals_sz - Number of items reg_vals can hold
* @param[out] num_regs - Number of registers returned by command
*
* @return SS_SUCCESS on success
*/
SS_STATUS dump_reg(int idx, addr_val_pair* reg_vals, int reg_vals_sz, int* num_regs);
/**
* @brief Enable a device on the SmartSensor
*
* @param[in] idx - Index of device
* @param[in] mode - Mode to set the device to
* @param[in] data_req - Data request
* @param[in] ext_ - Data request
*
* @return SS_SUCCESS on success
*/
SS_STATUS enable_sensor(int idx, int mode, ss_data_req* data_req, uint8_t ext_mode = SH_INPUT_DATA_DIRECT_SENSOR);
/**
* @brief Disable a device on the SmartSensor
*
* @param[in] idx - Index of device
*
* @return SS_SUCCESS on success
*/
SS_STATUS disable_sensor(int idx);
/**
* @brief Enable an algorithm on the SmartSensor
*
* @param[in] idx - Index of device
* @param[in] mode - Mode to set the device to
* @param[in] data_req - Data request
*
* @return SS_SUCCESS on success
*/
SS_STATUS enable_algo(int idx, int mode, ss_data_req* data_req);
/**
* @brief Disable an algorithm on the SmartSensor
*
* @param[in] idx - Index of device
*
* @return SS_SUCCESS on success
*/
SS_STATUS disable_algo(int idx);
/**
* @brief Set the value of an algorithm configuration parameter
*
* @param[in] algo_idx Index of algorithm
* @param[in] cfg_idx Index of configuration parameter
* @param[in] cfg Array of configuration bytes
* @param[in] cfg_sz Size of cfg array
*
* @return SS_SUCCESS on success
*/
SS_STATUS set_algo_cfg(int algo_idx, int cfg_idx, uint8_t *cfg, int cfg_sz);
/**
* @brief Get the value of an algorithm configuration parameter
*
* @param[in] algo_idx Index of algorithm
* @param[in] cfg_idx Index of configuration parameter
* @param[in] cfg Array of configuration bytes to be filled in
* @param[in] cfg_sz Number of bytes to be read
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_algo_cfg(int algo_idx, int cfg_idx, uint8_t *cfg, int cfg_sz);
/**
* @brief Set the CommChannel Output Mode options
*
* @param[in] data_type - Set to 0 for only algorithm data
* Set to 1 for only raw sensor data
* Set to 2 for algo + raw sensor data
* Set to 3 for no data
* @param[in] sc_en - Set to true to receive 1 byte sample count from SmartSensor
*
* @return SS_SUCCESS on success
*/
SS_STATUS set_data_type(int data_type, bool sc_en);
/**
* @brief Get the CommChannel Output Mode options
*
* @param[out] data_type - 0 for only algorithm data
* 1 for only raw sensor data
* 2 for algo + raw sensor data
* 3 for no data
* @param[in] sc_en - If true, SmartSensor prepends data with 1 byte sample count
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_data_type(int* data_type, bool *sc_en);
/**
* @brief Set the number of samples for the SmartSensor to collect
* before issuing an interrupt
*
* @param[in] thresh - Number of samples (1-255) to collect before interrupt
*
* @return SS_SUCCESS on success
*/
SS_STATUS set_fifo_thresh(int thresh);
/**
* @brief Get the number of samples the SmartSensor will collect
* before issuing an interrupt
*
* @param[out] thresh - Number of samples (1-255) collected before interrupt
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_fifo_thresh(int *thresh);
/**
* @brief Pass external sensor data to sensor hub
*
* @param[in] num_samples in tx_buf
* @param[in] tx_buf - Host sample data to send sensor hub
* @param[in] tx_buf_sz - Number of bytes of tx_buf
* @param[out] nb_written - Number of samples to sensor hub's input FIFO
*
* @return SS_SUCCESS on success
*/
SS_STATUS feed_to_input_fifo(uint8_t *tx_buf, int tx_buf_sz, int *nb_written);
/**
* @brief Get the number of sambes in Sensor FIFO
*
* @param[in] sensor_id - Sensor id to read FIFO size
* @param[out] fifo_size - Sensor's FIFO size
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_num_samples_in_sensor_fifo(uint8_t sensor_id, int *fifo_size);
/**
* @brief Get the total number of bytes in the Input FIFO
*
* @param[out] fifo_size - Input FIFO size
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_num_bytes_in_input_fifo(int *fifo_size);
/**
* @brief Get the total number of samples the Sensor's FIFO can hold
*
* @param[in] sensor_id - Sensor id to read FIFO size
* @param[out] fifo_size - Sensor's FIFO size
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_sensor_fifo_size(uint8_t sensor_id, int *fifo_size);
/**
* @brief Get the total number of samples the input FIFO can hold
*
* @param[out] fifo_size - Input FIFO size
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_input_fifo_size(int *fifo_size);
/**
* @brief Get the number of bytes per sample of a sensor
*
* @param[in] sensor_id - Sensor id to read sample size
* @param[out] sample_size - Sensor's sample size
*
* @return SS_SUCCESS on success
*/
SS_STATUS get_sensor_sample_size(uint8_t sensor_id, uint8_t *sample_size);
/**
* @brief send raw string to I2C
*
* @param[in] *rawdata - Raw data string, after slave address
* @param[out] rawdata_sz - Raw data size
*
* @return SS_SUCCESS on success
*/
SS_STATUS send_raw(uint8_t *rawdata, int rawdata_sz);
/**
* @brief Check that the SmartSensor is connected
*/
SS_STATUS ss_comm_check();
/**
* @brief Set if GPIO or CMD is used to enter bootloader and App
* before issuing an interrupt
*
* param[in] mode
* - 0: use command to enter bootloader mode
* - 1: use EBL GPIO to enter bootloader mode
*
* @return SS_SUCCESS on success
*/
SS_STATUS set_ebl_mode(uint8_t mode);
/**
* @brief Get ebl_mode value
*
* @return ebl_mode value
*/
int get_ebl_mode();
SS_STATUS stay_in_bootloader();
SS_STATUS exit_from_bootloader();
void enable_irq();
void disable_irq();
void mfio_selftest();
bool reset_mfio_irq();
void ss_execute_once();
void ss_clear_interrupt_flag();
private:
/* PRIVATE VARIABLES */
I2C *m_i2cBus;
SPI *m_spiBus;
DigitalInOut mfio_pin;
DigitalInOut reset_pin;
InterruptIn irq_pin;
char fw_version[128];
char algo_version[128];
const char* plat_name;
bool in_bootldr;
bool sc_en;
int data_type;
uint8_t ebl_mode; /* 0: Command bootloader, 1: No command, trigger GPIO */
int sensor_enabled_mode[SS_MAX_SUPPORTED_SENSOR_NUM];
int algo_enabled_mode[SS_MAX_SUPPORTED_ALGO_NUM];
ss_data_req* sensor_data_reqs[SS_MAX_SUPPORTED_SENSOR_NUM];
ss_data_req* algo_data_reqs[SS_MAX_SUPPORTED_ALGO_NUM];
/* PRIVATE METHODS */
SS_STATUS write_cmd_small(uint8_t *cmd_bytes, int cmd_bytes_len,
uint8_t *data, int data_len,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
SS_STATUS write_cmd_medium(uint8_t *cmd_bytes, int cmd_bytes_len,
uint8_t *data, int data_len,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
SS_STATUS write_cmd_large(uint8_t *cmd_bytes, int cmd_bytes_len,
uint8_t *data, int data_len,
int sleep_ms = SS_DEFAULT_CMD_SLEEP_MS);
void cfg_mfio(PinDirection);
void irq_handler();
volatile bool m_irq_received_;
void irq_handler_selftest();
volatile bool mfio_int_happened;
SS_STATUS read_fifo_data(int num_samples, int sample_size, uint8_t* databuf, int databuf_sz);
SS_STATUS num_avail_samples(int* num_samples);
SS_STATUS get_log_len(int *log_len);
SS_STATUS read_ss_log(int num_bytes, uint8_t *log_buf, int log_buf_sz);
void fifo_sample_size(int data_type, int* sample_size);
// EventStats irq_evt;
};
#endif