esp-idf/components/hal/esp32s3/include/hal/i2c_ll.h
SalimTerryLi 874a720286
soc/ll: workaround compiler bug that generate 8/16 bits inst instead of 32 bits one
update all struct headers to be more "standardized":

- bit fields are properly wrapped with struct
- bitwidth sum should be 32 within same struct, so that it's correctly padded with reserved bits
- bit field should be uint32_t
- typedef volatile struct xxx{} yyy;: xxx must exists. refer: https://github.com/espressif/esp-idf/pull/3199

added helper macros to force peripheral registers being accessed in 32 bitwidth

added a check script into ci
2021-08-30 13:50:58 +08:00

910 lines
25 KiB
C

// Copyright 2020 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// The LL layer for I2C register operations
#pragma once
#include "hal/misc.h"
#include "soc/i2c_periph.h"
#include "soc/soc_caps.h"
#include "soc/i2c_struct.h"
#include "hal/i2c_types.h"
#ifdef __cplusplus
extern "C" {
#endif
#define I2C_LL_INTR_MASK (0x3fff) /*!< I2C all interrupt bitmap */
/**
* @brief I2C hardware cmd register fields.
*/
typedef union {
struct {
uint32_t byte_num: 8,
ack_en: 1,
ack_exp: 1,
ack_val: 1,
op_code: 3,
reserved14: 17,
done: 1;
};
uint32_t val;
} i2c_hw_cmd_t;
/**
* @brief I2C interrupt event
*/
typedef enum {
I2C_INTR_EVENT_ERR,
I2C_INTR_EVENT_ARBIT_LOST, /*!< I2C arbition lost event */
I2C_INTR_EVENT_NACK, /*!< I2C NACK event */
I2C_INTR_EVENT_TOUT, /*!< I2C time out event */
I2C_INTR_EVENT_END_DET, /*!< I2C end detected event */
I2C_INTR_EVENT_TRANS_DONE, /*!< I2C trans done event */
I2C_INTR_EVENT_RXFIFO_FULL, /*!< I2C rxfifo full event */
I2C_INTR_EVENT_TXFIFO_EMPTY, /*!< I2C txfifo empty event */
} i2c_intr_event_t;
/**
* @brief Data structure for calculating I2C bus timing.
*/
typedef struct {
uint16_t clkm_div; /*!< I2C core clock divider */
uint16_t scl_low; /*!< I2C scl low period */
uint16_t scl_high; /*!< I2C scl hight period */
uint16_t scl_wait_high; /*!< I2C scl wait_high period */
uint16_t sda_hold; /*!< I2C scl low period */
uint16_t sda_sample; /*!< I2C sda sample time */
uint16_t setup; /*!< I2C start and stop condition setup period */
uint16_t hold; /*!< I2C start and stop condition hold period */
uint16_t tout; /*!< I2C bus timeout period */
} i2c_clk_cal_t;
// I2C operation mode command
#define I2C_LL_CMD_RESTART 6 /*!<I2C restart command */
#define I2C_LL_CMD_WRITE 1 /*!<I2C write command */
#define I2C_LL_CMD_READ 3 /*!<I2C read command */
#define I2C_LL_CMD_STOP 2 /*!<I2C stop command */
#define I2C_LL_CMD_END 4 /*!<I2C end command */
// Get the I2C hardware instance
#define I2C_LL_GET_HW(i2c_num) (((i2c_num) == 0) ? &I2C0 : &I2C1)
// Get the I2C hardware FIFO address
#define I2C_LL_GET_FIFO_ADDR(i2c_num) (I2C_DATA_APB_REG(i2c_num))
// I2C master TX interrupt bitmap
#define I2C_LL_MASTER_TX_INT (I2C_NACK_INT_ENA_M|I2C_TIME_OUT_INT_ENA_M|I2C_TRANS_COMPLETE_INT_ENA_M|I2C_ARBITRATION_LOST_INT_ENA_M|I2C_END_DETECT_INT_ENA_M)
// I2C master RX interrupt bitmap
#define I2C_LL_MASTER_RX_INT (I2C_TIME_OUT_INT_ENA_M|I2C_TRANS_COMPLETE_INT_ENA_M|I2C_ARBITRATION_LOST_INT_ENA_M|I2C_END_DETECT_INT_ENA_M)
// I2C slave TX interrupt bitmap
#define I2C_LL_SLAVE_TX_INT (I2C_TXFIFO_WM_INT_ENA_M)
// I2C slave RX interrupt bitmap
#define I2C_LL_SLAVE_RX_INT (I2C_RXFIFO_WM_INT_ENA_M | I2C_TRANS_COMPLETE_INT_ENA_M)
// I2C source clock
#define I2C_LL_CLK_SRC_FREQ(src_clk) (((src_clk) == I2C_SCLK_RTC) ? 8*1000*1000 : 40*1000*1000); // Another clock is XTAL clock
// I2C max timeout value
#define I2C_LL_MAX_TIMEOUT I2C_TIME_OUT_VALUE_V
/**
* @brief Calculate I2C bus frequency
* Note that the clock accuracy is affected by the external pull-up resistor,
* here we try to to calculate a configuration parameter which is close to the required clock.
* But in I2C communication, the clock accuracy is not very concerned.
*
* @param source_clk I2C source clock
* @param bus_freq I2C bus frequency
* @param clk_cal Pointer to accept the clock configuration
*
* @return None
*/
static inline void i2c_ll_cal_bus_clk(uint32_t source_clk, uint32_t bus_freq, i2c_clk_cal_t *clk_cal)
{
uint32_t clkm_div = source_clk / (bus_freq * 1024) +1;
uint32_t sclk_freq = source_clk / clkm_div;
uint32_t half_cycle = sclk_freq / bus_freq / 2;
//SCL
clk_cal->clkm_div = clkm_div;
clk_cal->scl_low = half_cycle;
// default, scl_wait_high < scl_high
clk_cal->scl_high = (bus_freq <= 50000) ? half_cycle : (half_cycle / 5 * 4 + 4);
clk_cal->scl_wait_high = half_cycle - clk_cal->scl_high;
clk_cal->sda_hold = half_cycle / 2;
// scl_wait_high < sda_sample <= scl_high
clk_cal->sda_sample = half_cycle / 2;
clk_cal->setup = half_cycle;
clk_cal->hold = half_cycle;
//default we set the timeout value to about 10 bus cycles
// log(20*half_cycle)/log(2) = log(half_cycle)/log(2) + log(20)/log(2)
clk_cal->tout = (int)(sizeof(half_cycle) * 8 - __builtin_clz(5 * half_cycle)) + 2;
}
/**
* @brief Update I2C configuration
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_update(i2c_dev_t *hw)
{
hw->ctr.conf_upgate = 1;
}
/**
* @brief Configure the I2C bus timing related register.
*
* @param hw Beginning address of the peripheral registers
* @param bus_cfg Pointer to the data structure holding the register configuration.
*
* @return None
*/
static inline void i2c_ll_set_bus_timing(i2c_dev_t *hw, i2c_clk_cal_t *bus_cfg)
{
HAL_FORCE_MODIFY_U32_REG_FIELD(hw->clk_conf, sclk_div_num, bus_cfg->clkm_div - 1);
//scl period
hw->scl_low_period.scl_low_period = bus_cfg->scl_low - 1;
hw->scl_high_period.scl_high_period = bus_cfg->scl_high;
//sda sample
hw->sda_hold.sda_hold_time = bus_cfg->sda_hold;
hw->sda_sample.sda_sample_time = bus_cfg->sda_sample;
//setup
hw->scl_rstart_setup.scl_rstart_setup_time = bus_cfg->setup;
hw->scl_stop_setup.scl_stop_setup_time = bus_cfg->setup;
//hold
hw->scl_start_hold.scl_start_hold_time = bus_cfg->hold - 1;
hw->scl_stop_hold.scl_stop_hold_time = bus_cfg->hold;
hw->to.time_out_value = bus_cfg->tout;
hw->to.time_out_en = 1;
}
/**
* @brief Reset I2C txFIFO
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_txfifo_rst(i2c_dev_t *hw)
{
hw->fifo_conf.tx_fifo_rst = 1;
hw->fifo_conf.tx_fifo_rst = 0;
}
/**
* @brief Reset I2C rxFIFO
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_rxfifo_rst(i2c_dev_t *hw)
{
hw->fifo_conf.rx_fifo_rst = 1;
hw->fifo_conf.rx_fifo_rst = 0;
}
/**
* @brief Configure I2C SCL timing
*
* @param hw Beginning address of the peripheral registers
* @param high_period The I2C SCL hight period (in core clock cycle, hight_period > 2)
* @param low_period The I2C SCL low period (in core clock cycle, low_period > 1)
*
* @return None.
*/
static inline void i2c_ll_set_scl_timing(i2c_dev_t *hw, int high_period, int low_period)
{
int high_period_output = high_period - 10; // The rising edge by open-drain output + internal pullup (about 50K) is slow
hw->scl_low_period.scl_low_period = low_period - 1;
hw->scl_high_period.scl_high_period = high_period_output;
hw->scl_high_period.scl_wait_high_period = high_period - high_period_output;
}
/**
* @brief Clear I2C interrupt status
*
* @param hw Beginning address of the peripheral registers
* @param mask Interrupt mask needs to be cleared
*
* @return None
*/
static inline void i2c_ll_clr_intsts_mask(i2c_dev_t *hw, uint32_t mask)
{
hw->int_clr.val = mask;
}
/**
* @brief Enable I2C interrupt
*
* @param hw Beginning address of the peripheral registers
* @param mask Interrupt mask needs to be enabled
*
* @return None
*/
static inline void i2c_ll_enable_intr_mask(i2c_dev_t *hw, uint32_t mask)
{
hw->int_ena.val |= mask;
}
/**
* @brief Disable I2C interrupt
*
* @param hw Beginning address of the peripheral registers
* @param mask Interrupt mask needs to be disabled
*
* @return None
*/
static inline void i2c_ll_disable_intr_mask(i2c_dev_t *hw, uint32_t mask)
{
hw->int_ena.val &= (~mask);
}
/**
* @brief Get I2C interrupt status
*
* @param hw Beginning address of the peripheral registers
*
* @return I2C interrupt status
*/
static inline uint32_t i2c_ll_get_intsts_mask(i2c_dev_t *hw)
{
return hw->int_status.val;
}
/**
* @brief Configure I2C memory access mode, FIFO mode or non-FIFO mode
*
* @param hw Beginning address of the peripheral registers
* @param fifo_mode_en Set true to enable FIFO access mode, else, set it false
*
* @return None
*/
static inline void i2c_ll_set_fifo_mode(i2c_dev_t *hw, bool fifo_mode_en)
{
hw->fifo_conf.nonfifo_en = fifo_mode_en ? 0 : 1;
}
/**
* @brief Configure I2C timeout
*
* @param hw Beginning address of the peripheral registers
* @param tout_num The I2C timeout value needs to be set (2^tout in core clock cycle)
*
* @return None
*/
static inline void i2c_ll_set_tout(i2c_dev_t *hw, int tout)
{
hw->to.time_out_value = tout;
}
/**
* @brief Configure I2C slave address
*
* @param hw Beginning address of the peripheral registers
* @param slave_addr I2C slave address needs to be set
* @param addr_10bit_en Set true to enable 10-bit slave address mode, set false to enable 7-bit address mode
*
* @return None
*/
static inline void i2c_ll_set_slave_addr(i2c_dev_t *hw, uint16_t slave_addr, bool addr_10bit_en)
{
hw->slave_addr.slave_addr = slave_addr;
hw->slave_addr.addr_10bit_en = addr_10bit_en;
}
/**
* @brief Write I2C hardware command register
*
* @param hw Beginning address of the peripheral registers
* @param cmd I2C hardware command
* @param cmd_idx The index of the command register, should be less than 16
*
* @return None
*/
static inline void i2c_ll_write_cmd_reg(i2c_dev_t *hw, i2c_hw_cmd_t cmd, int cmd_idx)
{
_Static_assert(sizeof(i2c_comd0_reg_t) == sizeof(i2c_hw_cmd_t),
"i2c_comdX_reg_t structure size must be equal to i2c_hw_cmd_t structure size");
volatile i2c_hw_cmd_t* commands = (volatile i2c_hw_cmd_t*) &hw->comd0;
commands[cmd_idx].val = cmd.val;
}
/**
* @brief Configure I2C start timing
*
* @param hw Beginning address of the peripheral registers
* @param start_setup The start condition setup period (in core clock cycle)
* @param start_hold The start condition hold period (in core clock cycle)
*
* @return None
*/
static inline void i2c_ll_set_start_timing(i2c_dev_t *hw, int start_setup, int start_hold)
{
hw->scl_rstart_setup.scl_rstart_setup_time = start_setup;
hw->scl_start_hold.scl_start_hold_time = start_hold - 1;
}
/**
* @brief Configure I2C stop timing
*
* @param hw Beginning address of the peripheral registers
* @param stop_setup The stop condition setup period (in core clock cycle)
* @param stop_hold The stop condition hold period (in core clock cycle)
*
* @return None
*/
static inline void i2c_ll_set_stop_timing(i2c_dev_t *hw, int stop_setup, int stop_hold)
{
hw->scl_stop_setup.scl_stop_setup_time = stop_setup;
hw->scl_stop_hold.scl_stop_hold_time = stop_hold;
}
/**
* @brief Configure I2C stop timing
*
* @param hw Beginning address of the peripheral registers
* @param sda_sample The SDA sample time (in core clock cycle)
* @param sda_hold The SDA hold time (in core clock cycle)
*
* @return None
*/
static inline void i2c_ll_set_sda_timing(i2c_dev_t *hw, int sda_sample, int sda_hold)
{
hw->sda_hold.sda_hold_time = sda_hold;
hw->sda_sample.sda_sample_time = sda_sample;
}
/**
* @brief Set I2C txFIFO empty threshold
*
* @param hw Beginning address of the peripheral registers
* @param empty_thr The txFIFO empty threshold
*
* @return None
*/
static inline void i2c_ll_set_txfifo_empty_thr(i2c_dev_t *hw, uint8_t empty_thr)
{
hw->fifo_conf.txfifo_wm_thrhd = empty_thr;
}
/**
* @brief Set I2C rxFIFO full threshold
*
* @param hw Beginning address of the peripheral registers
* @param full_thr The rxFIFO full threshold
*
* @return None
*/
static inline void i2c_ll_set_rxfifo_full_thr(i2c_dev_t *hw, uint8_t full_thr)
{
hw->fifo_conf.rxfifo_wm_thrhd = full_thr;
}
/**
* @brief Set the I2C data mode, LSB or MSB
*
* @param hw Beginning address of the peripheral registers
* @param tx_mode Tx data bit mode
* @param rx_mode Rx data bit mode
*
* @return None
*/
static inline void i2c_ll_set_data_mode(i2c_dev_t *hw, i2c_trans_mode_t tx_mode, i2c_trans_mode_t rx_mode)
{
hw->ctr.tx_lsb_first = tx_mode;
hw->ctr.rx_lsb_first = rx_mode;
}
/**
* @brief Get the I2C data mode
*
* @param hw Beginning address of the peripheral registers
* @param tx_mode Pointer to accept the received bytes mode
* @param rx_mode Pointer to accept the sended bytes mode
*
* @return None
*/
static inline void i2c_ll_get_data_mode(i2c_dev_t *hw, i2c_trans_mode_t *tx_mode, i2c_trans_mode_t *rx_mode)
{
*tx_mode = hw->ctr.tx_lsb_first;
*rx_mode = hw->ctr.rx_lsb_first;
}
/**
* @brief Get I2C sda timing configuration
*
* @param hw Beginning address of the peripheral registers
* @param sda_sample Pointer to accept the SDA sample timing configuration
* @param sda_hold Pointer to accept the SDA hold timing configuration
*
* @return None
*/
static inline void i2c_ll_get_sda_timing(i2c_dev_t *hw, int *sda_sample, int *sda_hold)
{
*sda_hold = hw->sda_hold.sda_hold_time;
*sda_sample = hw->sda_sample.sda_sample_time;
}
/**
* @brief Get the I2C hardware version
*
* @param hw Beginning address of the peripheral registers
*
* @return The I2C hardware version
*/
static inline uint32_t i2c_ll_get_hw_version(i2c_dev_t *hw)
{
return hw->date.val;
}
/**
* @brief Check if the I2C bus is busy
*
* @param hw Beginning address of the peripheral registers
*
* @return True if I2C state machine is busy, else false will be returned
*/
static inline bool i2c_ll_is_bus_busy(i2c_dev_t *hw)
{
return hw->sr.bus_busy;
}
/**
* @brief Check if I2C is master mode
*
* @param hw Beginning address of the peripheral registers
*
* @return True if I2C is master mode, else false will be returned
*/
static inline bool i2c_ll_is_master_mode(i2c_dev_t *hw)
{
return hw->ctr.ms_mode;
}
/**
* @brief Get the rxFIFO readable length
*
* @param hw Beginning address of the peripheral registers
*
* @return RxFIFO readable length
*/
static inline uint32_t i2c_ll_get_rxfifo_cnt(i2c_dev_t *hw)
{
return hw->sr.rxfifo_cnt;
}
/**
* @brief Get I2C txFIFO writable length
*
* @param hw Beginning address of the peripheral registers
*
* @return TxFIFO writable length
*/
static inline uint32_t i2c_ll_get_txfifo_len(i2c_dev_t *hw)
{
return SOC_I2C_FIFO_LEN - hw->sr.txfifo_cnt;
}
/**
* @brief Get I2C timeout configuration
*
* @param hw Beginning address of the peripheral registers
*
* @return The I2C timeout value
*/
static inline uint32_t i2c_ll_get_tout(i2c_dev_t *hw)
{
return hw->to.time_out_value;
}
/**
* @brief Start I2C transfer
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_trans_start(i2c_dev_t *hw)
{
hw->ctr.trans_start = 1;
}
/**
* @brief Get I2C start timing configuration
*
* @param hw Beginning address of the peripheral registers
* @param setup_time Pointer to accept the start condition setup period
* @param hold_time Pointer to accept the start condition hold period
*
* @return None
*/
static inline void i2c_ll_get_start_timing(i2c_dev_t *hw, int *setup_time, int *hold_time)
{
*setup_time = hw->scl_rstart_setup.scl_rstart_setup_time;
*hold_time = hw->scl_start_hold.scl_start_hold_time + 1;
}
/**
* @brief Get I2C stop timing configuration
*
* @param hw Beginning address of the peripheral registers
* @param setup_time Pointer to accept the stop condition setup period
* @param hold_time Pointer to accept the stop condition hold period
*
* @return None
*/
static inline void i2c_ll_get_stop_timing(i2c_dev_t *hw, int *setup_time, int *hold_time)
{
*setup_time = hw->scl_stop_setup.scl_stop_setup_time;
*hold_time = hw->scl_stop_hold.scl_stop_hold_time;
}
/**
* @brief Get I2C SCL timing configuration
*
* @param hw Beginning address of the peripheral registers
* @param high_period Pointer to accept the SCL high period
* @param low_period Pointer to accept the SCL low period
*
* @return None
*/
static inline void i2c_ll_get_scl_timing(i2c_dev_t *hw, int *high_period, int *low_period)
{
*high_period = hw->scl_high_period.scl_high_period + hw->scl_high_period.scl_wait_high_period;
*low_period = hw->scl_low_period.scl_low_period + 1;
}
/**
* @brief Write the I2C hardware txFIFO
*
* @param hw Beginning address of the peripheral registers
* @param ptr Pointer to data buffer
* @param len Amount of data needs to be writen
*
* @return None.
*/
static inline void i2c_ll_write_txfifo(i2c_dev_t *hw, uint8_t *ptr, uint8_t len)
{
for (int i = 0; i< len; i++) {
HAL_FORCE_MODIFY_U32_REG_FIELD(hw->data, fifo_rdata, ptr[i]);
}
}
/**
* @brief Read the I2C hardware rxFIFO
*
* @param hw Beginning address of the peripheral registers
* @param ptr Pointer to data buffer
* @param len Amount of data needs read
*
* @return None
*/
static inline void i2c_ll_read_rxfifo(i2c_dev_t *hw, uint8_t *ptr, uint8_t len)
{
for(int i = 0; i < len; i++) {
ptr[i] = HAL_FORCE_READ_U32_REG_FIELD(hw->data, fifo_rdata);
}
}
/**
* @brief Configure I2C hardware filter
*
* @param hw Beginning address of the peripheral registers
* @param filter_num If the glitch period on the line is less than this value, it can be filtered out
* If `filter_num == 0`, the filter will be disabled
*
* @return None
*/
static inline void i2c_ll_set_filter(i2c_dev_t *hw, uint8_t filter_num)
{
if (filter_num > 0) {
hw->filter_cfg.scl_filter_thres = filter_num;
hw->filter_cfg.sda_filter_thres = filter_num;
hw->filter_cfg.scl_filter_en = 1;
hw->filter_cfg.sda_filter_en = 1;
} else {
hw->filter_cfg.scl_filter_en = 0;
hw->filter_cfg.sda_filter_en = 0;
}
}
/**
* @brief Get I2C hardware filter configuration
*
* @param hw Beginning address of the peripheral registers
*
* @return The hardware filter configuration
*/
static inline uint8_t i2c_ll_get_filter(i2c_dev_t *hw)
{
return hw->filter_cfg.scl_filter_thres;
}
/**
* @brief Enable I2C master TX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_enable_tx_it(i2c_dev_t *hw)
{
hw->int_clr.val = ~0;
hw->int_ena.val = I2C_LL_MASTER_TX_INT;
}
/**
* @brief Enable I2C master RX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_enable_rx_it(i2c_dev_t *hw)
{
hw->int_clr.val = ~0;
hw->int_ena.val = I2C_LL_MASTER_RX_INT;
}
/**
* @brief Disable I2C master TX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_disable_tx_it(i2c_dev_t *hw)
{
hw->int_ena.val &= (~I2C_LL_MASTER_TX_INT);
}
/**
* @brief Disable I2C master RX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_disable_rx_it(i2c_dev_t *hw)
{
hw->int_ena.val &= (~I2C_LL_MASTER_RX_INT);
}
/**
* @brief Clear I2C master TX interrupt status register
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_clr_tx_it(i2c_dev_t *hw)
{
hw->int_clr.val = I2C_LL_MASTER_TX_INT;
}
/**
* @brief Clear I2C master RX interrupt status register
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_clr_rx_it(i2c_dev_t *hw)
{
hw->int_clr.val = I2C_LL_MASTER_RX_INT;
}
/**
* @brief
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_enable_tx_it(i2c_dev_t *hw)
{
hw->int_ena.val |= I2C_LL_SLAVE_TX_INT;
}
/**
* @brief Enable I2C slave RX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_enable_rx_it(i2c_dev_t *hw)
{
hw->int_ena.val |= I2C_LL_SLAVE_RX_INT;
}
/**
* @brief Disable I2C slave TX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_disable_tx_it(i2c_dev_t *hw)
{
hw->int_ena.val &= (~I2C_LL_SLAVE_TX_INT);
}
/**
* @brief Disable I2C slave RX interrupt
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_disable_rx_it(i2c_dev_t *hw)
{
hw->int_ena.val &= (~I2C_LL_SLAVE_RX_INT);
}
/**
* @brief Clear I2C slave TX interrupt status register
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_clr_tx_it(i2c_dev_t *hw)
{
hw->int_clr.val = I2C_LL_SLAVE_TX_INT;
}
/**
* @brief Clear I2C slave RX interrupt status register.
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_clr_rx_it(i2c_dev_t *hw)
{
hw->int_clr.val = I2C_LL_SLAVE_RX_INT;
}
/**
* @brief Reste I2C master FSM. When the master FSM is stuck, call this function to reset the FSM
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_fsm_rst(i2c_dev_t *hw)
{
hw->ctr.fsm_rst = 1;
}
/**
* @brief Clear I2C bus, when the slave is stuck in a deadlock and keeps pulling the bus low,
* master can controls the SCL bus to generate 9 CLKs.
*
* Note: The master cannot detect if deadlock happens, but when the scl_st_to interrupt is generated, a deadlock may occur.
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_clr_bus(i2c_dev_t *hw)
{
hw->scl_sp_conf.scl_rst_slv_num = 9;
hw->scl_sp_conf.scl_rst_slv_en = 0;
hw->ctr.conf_upgate = 1;
hw->scl_sp_conf.scl_rst_slv_en = 1;
}
/**
* @brief Set I2C source clock
*
* @param hw Beginning address of the peripheral registers
* @param src_clk Source clock of the I2C
*
* @return None
*/
static inline void i2c_ll_set_source_clk(i2c_dev_t *hw, i2c_sclk_t src_clk)
{
hw->clk_conf.sclk_sel = (src_clk == I2C_SCLK_RTC) ? 1 : 0;
}
/**
* @brief Get I2C master interrupt event
*
* @param hw Beginning address of the peripheral registers
* @param event Pointer to accept the interrupt event
*
* @return None
*/
static inline void i2c_ll_master_get_event(i2c_dev_t *hw, i2c_intr_event_t *event)
{
typeof(hw->int_status) int_sts = hw->int_status;
if (int_sts.arbitration_lost_int_st) {
*event = I2C_INTR_EVENT_ARBIT_LOST;
} else if (int_sts.nack_int_st) {
*event = I2C_INTR_EVENT_NACK;
} else if (int_sts.time_out_int_st) {
*event = I2C_INTR_EVENT_TOUT;
} else if (int_sts.end_detect_int_st) {
*event = I2C_INTR_EVENT_END_DET;
} else if (int_sts.trans_complete_int_st) {
*event = I2C_INTR_EVENT_TRANS_DONE;
} else {
*event = I2C_INTR_EVENT_ERR;
}
}
/**
* @brief Get I2C slave interrupt event
*
* @param hw Beginning address of the peripheral registers
* @param event Pointer to accept the interrupt event
*
* @return None
*/
static inline void i2c_ll_slave_get_event(i2c_dev_t *hw, i2c_intr_event_t *event)
{
typeof(hw->int_status) int_sts = hw->int_status;
if (int_sts.txfifo_wm_int_st) {
*event = I2C_INTR_EVENT_TXFIFO_EMPTY;
} else if (int_sts.trans_complete_int_st) {
*event = I2C_INTR_EVENT_TRANS_DONE;
} else if (int_sts.rxfifo_wm_int_st) {
*event = I2C_INTR_EVENT_RXFIFO_FULL;
} else {
*event = I2C_INTR_EVENT_ERR;
}
}
/**
* @brief Init I2C master
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_master_init(i2c_dev_t *hw)
{
typeof(hw->ctr) ctrl_reg;
ctrl_reg.val = 0;
ctrl_reg.ms_mode = 1;
ctrl_reg.clk_en = 1;
ctrl_reg.sda_force_out = 1;
ctrl_reg.scl_force_out = 1;
hw->ctr.val = ctrl_reg.val;
}
/**
* @brief Init I2C slave
*
* @param hw Beginning address of the peripheral registers
*
* @return None
*/
static inline void i2c_ll_slave_init(i2c_dev_t *hw)
{
typeof(hw->ctr) ctrl_reg;
ctrl_reg.val = 0;
ctrl_reg.sda_force_out = 1;
ctrl_reg.scl_force_out = 1;
hw->ctr.val = ctrl_reg.val;
hw->ctr.slv_tx_auto_start_en = 1;
hw->fifo_conf.fifo_addr_cfg_en = 0;
}
#ifdef __cplusplus
}
#endif