drivers/i2c/i2c_gd32.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2021 BrainCo Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #define DT_DRV_COMPAT gd_gd32_i2c

 #include <errno.h>
 #include <zephyr/kernel.h>
 #include <zephyr/devicetree.h>
 #include <zephyr/drivers/pinctrl.h>
 #include <zephyr/drivers/i2c.h>

 #include <gd32_i2c.h>
 #include <gd32_rcu.h>

 #include <zephyr/logging/log.h>
 LOG_MODULE_REGISTER(i2c_gd32, CONFIG_I2C_LOG_LEVEL);

 #include "i2c-priv.h"

 /* Bus error */
 #define I2C_GD32_ERR_BERR BIT(0)
 /* Arbitration lost */
 #define I2C_GD32_ERR_LARB BIT(1)
 /* No ACK received */
 #define I2C_GD32_ERR_AERR BIT(2)

 struct i2c_gd32_config {
 	uint32_t reg;
 	uint32_t bitrate;
 	uint32_t rcu_periph_clock;
 	const struct pinctrl_dev_config *pcfg;
 	void (*irq_cfg_func)(void);
 };

 struct i2c_gd32_data {
 	struct k_sem bus_mutex;
 	struct k_sem sync_sem;
 	uint32_t dev_config;
 	uint16_t addr1;
 	uint16_t addr2;
 	uint32_t xfer_len;
 	struct i2c_msg *current;
 	uint8_t errs;
 	bool is_stopped;
 	bool is_restart;
 };

 static inline void i2c_gd32_enable_interrupts(const struct i2c_gd32_config *cfg)
 {
 	I2C_CTL1(cfg->reg) |= I2C_CTL1_ERRIE;
 	I2C_CTL1(cfg->reg) |= I2C_CTL1_EVIE;
 	I2C_CTL1(cfg->reg) |= I2C_CTL1_BUFIE;
 }

 static inline void i2c_gd32_disable_interrupts(const struct i2c_gd32_config *cfg)
 {
 	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_ERRIE;
 	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_EVIE;
 	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
 }

 static inline void i2c_gd32_xfer_read(struct i2c_gd32_data *data,
 				      const struct i2c_gd32_config *cfg)
 {
 	data->current->len--;
 	*data->current->buf = I2C_DATA(cfg->reg);
 	data->current->buf++;

 	if ((data->xfer_len > 0U) &&
 	    (data->current->len == 0U)) {
 		data->current++;
 	}
 }

 static inline void i2c_gd32_xfer_write(struct i2c_gd32_data *data,
 				       const struct i2c_gd32_config *cfg)
 {
 	data->current->len--;
 	I2C_DATA(cfg->reg) = *data->current->buf;
 	data->current->buf++;

 	if ((data->xfer_len > 0U) &&
 	    (data->current->len == 0U)) {
 		data->current++;
 	}
 }

 static void i2c_gd32_handle_rbne(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	switch (data->xfer_len) {
 	case 0:
 		/* Unwanted data received, ignore it. */
 		k_sem_give(&data->sync_sem);
 		break;
 	case 1:
 		/* If total_read_length == 1, read the data directly. */
 		data->xfer_len--;
 		i2c_gd32_xfer_read(data, cfg);

 		k_sem_give(&data->sync_sem);

 		break;
 	case 2:
 		__fallthrough;
 	case 3:
 		/*
 		 * If total_read_length == 2, or total_read_length > 3
 		 * and remaining_read_length == 3, disable the RBNE
 		 * interrupt.
 		 * Remaining data will be read from BTC interrupt.
 		 */
 		I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
 		break;
 	default:
 		/*
 		 * If total_read_length > 3 and remaining_read_length > 3,
 		 * read the data directly.
 		 */
 		data->xfer_len--;
 		i2c_gd32_xfer_read(data, cfg);
 		break;
 	}

 }

 static void i2c_gd32_handle_tbe(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	if (data->xfer_len > 0U) {
 		data->xfer_len--;
 		if (data->xfer_len == 0U) {
 			/*
 			 * This is the last data to transmit, disable the TBE interrupt.
 			 * Use the BTC interrupt to indicate the write data complete state.
 			 */
 			I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
 		}
 		i2c_gd32_xfer_write(data, cfg);

 	} else {
 		if ((data->current->flags & I2C_MSG_STOP) &&
 		    (data->is_stopped == false)) {
 			data->is_stopped = true;
 			/* Enter stop condition */
 			I2C_CTL0(cfg->reg) |= I2C_CTL0_STOP;
 		}

 		if (I2C_STAT0(cfg->reg) & I2C_STAT0_BTC) {
 			/* Clear BTC bit */
 			I2C_DATA(cfg->reg);
 		}

 		k_sem_give(&data->sync_sem);
 	}
 }

 static void i2c_gd32_handle_btc(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	if (data->current->flags & I2C_MSG_READ) {
 		uint32_t counter = 0U;

 		switch (data->xfer_len) {
 		case 2:
 			/*
 			 * Stop condition must be generated before reading the
 			 * last two bytes.
 			 */
 			if ((data->current->flags & I2C_MSG_STOP) &&
 			    (data->is_stopped == false)) {
 				data->is_stopped = true;
 				/* Enter stop condition */
 				I2C_CTL0(cfg->reg) |= I2C_CTL0_STOP;
 			}

 			for (counter = 2U; counter > 0; counter--) {
 				data->xfer_len--;
 				i2c_gd32_xfer_read(data, cfg);
 			}

 			k_sem_give(&data->sync_sem);

 			break;
 		case 3:
 			/* Clear ACKEN bit */
 			I2C_CTL0(cfg->reg) &= ~I2C_CTL0_ACKEN;

 			data->xfer_len--;
 			i2c_gd32_xfer_read(data, cfg);

 			break;
 		default:
 			i2c_gd32_handle_rbne(dev);
 			break;
 		}
 	} else {
 		i2c_gd32_handle_tbe(dev);
 	}
 }

 static void i2c_gd32_handle_addsend(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	if (data->is_restart) {
 		/* Clear ADDSEND bit */
 		I2C_STAT1(cfg->reg);

 		data->is_restart = false;
 		data->current->flags &= ~I2C_MSG_RW_MASK;
 		data->current->flags |= I2C_MSG_READ;
 		/* Enter repeated start condition */
 		I2C_CTL0(cfg->reg) |= I2C_CTL0_START;

 		return;
 	}

 	if ((data->current->flags & I2C_MSG_READ) &&
 	    (data->xfer_len <= 2U)) {
 		I2C_CTL0(cfg->reg) &= ~I2C_CTL0_ACKEN;
 	}

 	/* Clear ADDSEND bit */
 	I2C_STAT1(cfg->reg);

 	if ((data->xfer_len == 1U) &&
 	    (data->current->flags & I2C_MSG_STOP) &&
 	    (data->current->flags & I2C_MSG_READ)) {
 		data->is_stopped = true;
 		/* Enter stop condition */
 		I2C_CTL0(cfg->reg) |= I2C_CTL0_STOP;
 	}

 }

 static void i2c_gd32_event_isr(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;
 	uint32_t stat;

 	stat = I2C_STAT0(cfg->reg);

 	if (stat & I2C_STAT0_SBSEND) {
 		if (data->current->flags & I2C_MSG_READ) {
 			I2C_DATA(cfg->reg) = (data->addr1 << 1U) | 1U;
 		} else {
 			I2C_DATA(cfg->reg) = (data->addr1 << 1U) | 0U;
 		}
 	} else if (stat & I2C_STAT0_ADD10SEND) {
 		I2C_DATA(cfg->reg) = data->addr2;
 	} else if (stat & I2C_STAT0_ADDSEND) {
 		i2c_gd32_handle_addsend(dev);
 	} else if (stat & I2C_STAT0_BTC) {
 		i2c_gd32_handle_btc(dev);
 	} else if (stat & I2C_STAT0_RBNE) {
 		i2c_gd32_handle_rbne(dev);
 	} else if (stat & I2C_STAT0_TBE) {
 		i2c_gd32_handle_tbe(dev);
 	}
 }

 static void i2c_gd32_error_isr(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;
 	uint32_t stat;

 	stat = I2C_STAT0(cfg->reg);

 	if (stat & I2C_STAT0_BERR) {
 		I2C_STAT0(cfg->reg) &= ~I2C_STAT0_BERR;
 		data->errs |= I2C_GD32_ERR_BERR;
 	}

 	if (stat & I2C_STAT0_LOSTARB) {
 		I2C_STAT0(cfg->reg) &= ~I2C_STAT0_LOSTARB;
 		data->errs |= I2C_GD32_ERR_LARB;
 	}

 	if (stat & I2C_STAT0_AERR) {
 		I2C_STAT0(cfg->reg) &= ~I2C_STAT0_AERR;
 		data->errs |= I2C_GD32_ERR_AERR;
 	}

 	if (data->errs != 0U) {
 		k_sem_give(&data->sync_sem);
 	}
 }

 static void i2c_gd32_log_err(struct i2c_gd32_data *data)
 {
 	if (data->errs & I2C_GD32_ERR_BERR) {
 		LOG_ERR("Bus error");
 	}

 	if (data->errs & I2C_GD32_ERR_LARB) {
 		LOG_ERR("Arbitration lost");
 	}

 	if (data->errs & I2C_GD32_ERR_AERR) {
 		LOG_ERR("No ACK received");
 	}
 }

 static void i2c_gd32_xfer_begin(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	k_sem_reset(&data->sync_sem);

 	data->errs = 0U;
 	data->is_restart = false;
 	data->is_stopped = false;

 	/* Enable i2c device */
 	I2C_CTL0(cfg->reg) |= I2C_CTL0_I2CEN;

 	if (data->current->flags & I2C_MSG_READ) {
 		/* Default to set ACKEN bit. */
 		I2C_CTL0(cfg->reg) |= I2C_CTL0_ACKEN;

 		/* For 2 bytes read, use POAP bit to give NACK for the last data receiving. */
 		if (data->xfer_len == 2U) {
 			I2C_CTL0(cfg->reg) |= I2C_CTL0_POAP;
 		}

 		/*
 		 * For read on 10 bits address mode, start condition will happen twice.
 		 * Transfer sequence as below:
 		 *   S addr1+W addr2 S addr1+R
 		 * Use a is_restart flag to cover this case.
 		 */
 		if (data->dev_config & I2C_ADDR_10_BITS) {
 			data->is_restart = true;
 			data->current->flags &= ~I2C_MSG_RW_MASK;
 		}
 	}

 	/* Enter repeated start condition */
 	I2C_CTL0(cfg->reg) |= I2C_CTL0_START;
 }

 static int i2c_gd32_xfer_end(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	i2c_gd32_disable_interrupts(cfg);

 	if (data->errs != 0U) {
 		/* Disable i2c device */
 		I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;
 		i2c_gd32_log_err(data);
 		data->errs = 0U;

 		return -EIO;
 	}

 	if (data->current->flags & I2C_MSG_STOP) {
 		/* Wait for stop condition is done. */
 		while (I2C_STAT1(cfg->reg) & I2C_STAT1_I2CBSY) {
 			/* NOP */
 		}
 		/* Disable I2C device */
 		I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;
 	}

 	return 0;
 }

 static int i2c_gd32_msg_read(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	i2c_gd32_xfer_begin(dev);

 	/* For repeated start condition, wait for TBE cleared. */
 	while (I2C_STAT0(cfg->reg) & I2C_STAT0_TBE) {
 		/* NOP */
 	}

 	i2c_gd32_enable_interrupts(cfg);

 	k_sem_take(&data->sync_sem, K_FOREVER);

 	return i2c_gd32_xfer_end(dev);
 }

 static int i2c_gd32_msg_write(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;

 	i2c_gd32_xfer_begin(dev);

 	/* For repeated start condition, wait for RBNE cleared. */
 	while (I2C_STAT0(cfg->reg) & I2C_STAT0_RBNE) {
 		/* NOP */
 	}

 	i2c_gd32_enable_interrupts(cfg);

 	k_sem_take(&data->sync_sem, K_FOREVER);

 	return i2c_gd32_xfer_end(dev);
 }

 static int i2c_gd32_transfer(const struct device *dev,
 			     struct i2c_msg *msgs,
 			     uint8_t num_msgs,
 			     uint16_t addr)
 {
 	struct i2c_gd32_data *data = dev->data;
 	struct i2c_msg *current, *next;
 	uint8_t itr;
 	int err = 0;

 	current = msgs;

 	/* First message flags implicitly contain I2C_MSG_RESTART flag. */
 	current->flags |= I2C_MSG_RESTART;

 	for (uint8_t i = 1; i <= num_msgs; i++) {

 		if (i < num_msgs) {
 			next = current + 1;

 			/*
 			 * If there have a R/W transfer state change between messages,
 			 * An explicit I2C_MSG_RESTART flag is needed for the second message.
 			 */
 			if ((current->flags & I2C_MSG_RW_MASK) !=
 			(next->flags & I2C_MSG_RW_MASK)) {
 				if ((next->flags & I2C_MSG_RESTART) == 0U) {
 					return -EINVAL;
 				}
 			}

 			/* Only the last message need I2C_MSG_STOP flag to free the Bus. */
 			if (current->flags & I2C_MSG_STOP) {
 				return -EINVAL;
 			}
 		} else {
 			/* Last message flags implicitly contain I2C_MSG_STOP flag. */
 			current->flags |= I2C_MSG_STOP;
 		}

 		if ((current->buf == NULL) ||
 		    (current->len == 0U)) {
 			return -EINVAL;
 		}

 		current++;
 	}

 	k_sem_take(&data->bus_mutex, K_FOREVER);

 	if (data->dev_config & I2C_ADDR_10_BITS) {
 		data->addr1 = 0xF0 | ((addr & BITS(8, 9)) >> 8U);
 		data->addr2 = addr & BITS(0, 7);
 	} else {
 		data->addr1 = addr & BITS(0, 6);
 	}

 	for (uint8_t i = 0; i < num_msgs; i = itr) {
 		data->current = &msgs[i];
 		data->xfer_len = msgs[i].len;

 		for (itr = i + 1; itr < num_msgs; itr++) {
 			if ((data->current->flags & I2C_MSG_RW_MASK) !=
 			    (msgs[itr].flags & I2C_MSG_RW_MASK)) {
 				break;
 			}
 			data->xfer_len += msgs[itr].len;
 		}

 		if (data->current->flags & I2C_MSG_READ) {
 			err = i2c_gd32_msg_read(dev);
 		} else {
 			err = i2c_gd32_msg_write(dev);
 		}

 		if (err < 0) {
 			break;
 		}
 	}

 	k_sem_give(&data->bus_mutex);

 	return err;
 }

 static int i2c_gd32_configure(const struct device *dev,
 			      uint32_t dev_config)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;
 	uint32_t pclk1, freq, clkc;
 	int err = 0;

 	k_sem_take(&data->bus_mutex, K_FOREVER);

 	/* Disable I2C device */
 	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;

 	/* GD32 i2c interface always connect to APB1. */
 	pclk1 = rcu_clock_freq_get(CK_APB1);

 	/* i2c clock frequency, us */
 	freq = pclk1 / 1000000U;
 	if (freq > I2CCLK_MAX) {
 		LOG_ERR("I2C max clock freq %u, current is %u\n",
 			I2CCLK_MAX, freq);
 		err = -ENOTSUP;
 		goto error;
 	}

 	/*
 	 * Refer from SoC user manual.
 	 * In standard mode:
 	 *   T_high = CLKC * T_pclk1
 	 *   T_low  = CLKC * T_pclk1
 	 *
 	 * In fast mode and fast mode plus with DTCY=1:
 	 *   T_high = 9 * CLKC * T_pclk1
 	 *   T_low  = 16 * CLKC * T_pclk1
 	 *
 	 * T_pclk1 is reciprocal of pclk1:
 	 *   T_pclk1 = 1 / pclk1
 	 *
 	 * T_high and T_low construct the bit transfer:
 	 *  T_high + T_low = 1 / bitrate
 	 *
 	 * And then, we can get the CLKC equation.
 	 * Standard mode:
 	 *   CLKC = pclk1 / (bitrate * 2)
 	 * Fast mode and fast mode plus:
 	 *   CLKC = pclk1 / (bitrate * 25)
 	 *
 	 * Variable list:
 	 *   T_high:  high period of the SCL clock
 	 *   T_low:   low period of the SCL clock
 	 *   T_pclk1: duration of single pclk1 pulse
 	 *   pclk1:   i2c device clock frequency
 	 *   bitrate: 100 Kbits for standard mode
 	 */
 	switch (I2C_SPEED_GET(dev_config)) {
 	case I2C_SPEED_STANDARD:
 		if (freq < I2CCLK_MIN) {
 			LOG_ERR("I2C standard-mode min clock freq %u, current is %u\n",
 				I2CCLK_MIN, freq);
 			err = -ENOTSUP;
 			goto error;
 		}
 		I2C_CTL1(cfg->reg) &= ~I2C_CTL1_I2CCLK;
 		I2C_CTL1(cfg->reg) |= freq;

 		/* Standard-mode risetime maximum value: 1000ns */
 		if (freq == I2CCLK_MAX) {
 			I2C_RT(cfg->reg) = I2CCLK_MAX;
 		} else {
 			I2C_RT(cfg->reg) = freq + 1U;
 		}

 		/* CLKC = pclk1 / (bitrate * 2) */
 		clkc = pclk1 / (I2C_BITRATE_STANDARD * 2U);

 		I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
 		I2C_CKCFG(cfg->reg) |= clkc;
 		/* standard-mode */
 		I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_FAST;

 		break;
 	case I2C_SPEED_FAST:
 		if (freq < I2CCLK_FM_MIN) {
 			LOG_ERR("I2C fast-mode min clock freq %u, current is %u\n",
 				I2CCLK_FM_MIN, freq);
 			err = -ENOTSUP;
 			goto error;
 		}

 		/* Fast-mode risetime maximum value: 300ns */
 		I2C_RT(cfg->reg) = freq * 300U / 1000U + 1U;

 		/* CLKC = pclk1 / (bitrate * 25) */
 		clkc = pclk1 / (I2C_BITRATE_FAST_PLUS * 25U);
 		if (clkc == 0U) {
 			clkc = 1U;
 		}

 		/* Default DCTY to 1 */
 		I2C_CKCFG(cfg->reg) |= I2C_CKCFG_DTCY;
 		I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
 		I2C_CKCFG(cfg->reg) |= clkc;
 		/* Transfer mode: fast-mode */
 		I2C_CKCFG(cfg->reg) |= I2C_CKCFG_FAST;

 #ifdef I2C_FMPCFG
 		/* Disable transfer mode: fast-mode plus */
 		I2C_FMPCFG(cfg->reg) &= ~I2C_FMPCFG_FMPEN;
 #endif /* I2C_FMPCFG */

 		break;
 #ifdef I2C_FMPCFG
 	case I2C_SPEED_FAST_PLUS:
 		if (freq < I2CCLK_FM_PLUS_MIN) {
 			LOG_ERR("I2C fast-mode plus min clock freq %u, current is %u\n",
 				I2CCLK_FM_PLUS_MIN, freq);
 			err = -ENOTSUP;
 			goto error;
 		}

 		/* Fast-mode plus risetime maximum value: 120ns */
 		I2C_RT(cfg->reg) = freq * 120U / 1000U + 1U;

 		/* CLKC = pclk1 / (bitrate * 25) */
 		clkc = pclk1 / (I2C_BITRATE_FAST_PLUS * 25U);
 		if (clkc == 0U) {
 			clkc = 1U;
 		}

 		/* Default DCTY to 1 */
 		I2C_CKCFG(cfg->reg) |= I2C_CKCFG_DTCY;
 		I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
 		I2C_CKCFG(cfg->reg) |= clkc;
 		/* Transfer mode: fast-mode */
 		I2C_CKCFG(cfg->reg) |= I2C_CKCFG_FAST;

 		/* Enable transfer mode: fast-mode plus */
 		I2C_FMPCFG(cfg->reg) |= I2C_FMPCFG_FMPEN;

 		break;
 #endif /* I2C_FMPCFG */
 	default:
 		err = -EINVAL;
 		goto error;
 	}

 	data->dev_config = dev_config;
 error:
 	k_sem_give(&data->bus_mutex);

 	return err;
 }

 static struct i2c_driver_api i2c_gd32_driver_api = {
 	.configure = i2c_gd32_configure,
 	.transfer = i2c_gd32_transfer,
 };

 static int i2c_gd32_init(const struct device *dev)
 {
 	struct i2c_gd32_data *data = dev->data;
 	const struct i2c_gd32_config *cfg = dev->config;
 	uint32_t bitrate_cfg;
 	int err;

 	err = pinctrl_apply_state(cfg->pcfg, PINCTRL_STATE_DEFAULT);
 	if (err < 0) {
 		return err;
 	}

 	/* Mutex semaphore to protect the i2c api in multi-thread env. */
 	k_sem_init(&data->bus_mutex, 1, 1);

 	/* Sync semaphore to sync i2c state between isr and transfer api. */
 	k_sem_init(&data->sync_sem, 0, K_SEM_MAX_LIMIT);

 	rcu_periph_clock_enable(cfg->rcu_periph_clock);

 	cfg->irq_cfg_func();

 	bitrate_cfg = i2c_map_dt_bitrate(cfg->bitrate);

 	i2c_gd32_configure(dev, I2C_MODE_MASTER | bitrate_cfg);

 	return 0;
 }

 #define I2C_GD32_INIT(inst)							\
 	PINCTRL_DT_INST_DEFINE(inst);						\
 	static void i2c_gd32_irq_cfg_func_##inst(void)				\
 	{									\
 		IRQ_CONNECT(DT_INST_IRQ_BY_NAME(inst, event, irq),		\
 			    DT_INST_IRQ_BY_NAME(inst, event, priority),		\
 			    i2c_gd32_event_isr,					\
 			    DEVICE_DT_INST_GET(inst),				\
 			    0);							\
 		irq_enable(DT_INST_IRQ_BY_NAME(inst, event, irq));		\
 										\
 		IRQ_CONNECT(DT_INST_IRQ_BY_NAME(inst, error, irq),		\
 			    DT_INST_IRQ_BY_NAME(inst, error, priority),		\
 			    i2c_gd32_error_isr,					\
 			    DEVICE_DT_INST_GET(inst),				\
 			    0);							\
 		irq_enable(DT_INST_IRQ_BY_NAME(inst, error, irq));		\
 	}									\
 	static struct i2c_gd32_data i2c_gd32_data_##inst;			\
 	const static struct i2c_gd32_config i2c_gd32_cfg_##inst = {		\
 		.reg = DT_INST_REG_ADDR(inst),					\
 		.bitrate = DT_INST_PROP(inst, clock_frequency),			\
 		.rcu_periph_clock = DT_INST_PROP(inst, rcu_periph_clock),	\
 		.pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(inst),			\
 		.irq_cfg_func = i2c_gd32_irq_cfg_func_##inst,			\
 	};									\
 	I2C_DEVICE_DT_INST_DEFINE(inst,						\
 				  i2c_gd32_init, NULL,				\
 				  &i2c_gd32_data_##inst, &i2c_gd32_cfg_##inst,	\
 				  POST_KERNEL, CONFIG_I2C_INIT_PRIORITY,	\
 				  &i2c_gd32_driver_api);			\

 DT_INST_FOREACH_STATUS_OKAY(I2C_GD32_INIT)
	/*
	* Copyright (c) 2021 BrainCo Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#define DT_DRV_COMPAT gd_gd32_i2c

	#include <errno.h>
	#include <zephyr/kernel.h>
	#include <zephyr/devicetree.h>
	#include <zephyr/drivers/pinctrl.h>
	#include <zephyr/drivers/i2c.h>

	#include <gd32_i2c.h>
	#include <gd32_rcu.h>

	#include <zephyr/logging/log.h>
	LOG_MODULE_REGISTER(i2c_gd32, CONFIG_I2C_LOG_LEVEL);

	#include "i2c-priv.h"

	/* Bus error */
	#define I2C_GD32_ERR_BERR BIT(0)
	/* Arbitration lost */
	#define I2C_GD32_ERR_LARB BIT(1)
	/* No ACK received */
	#define I2C_GD32_ERR_AERR BIT(2)

	struct i2c_gd32_config {
	uint32_t reg;
	uint32_t bitrate;
	uint32_t rcu_periph_clock;
	const struct pinctrl_dev_config *pcfg;
	void (*irq_cfg_func)(void);
	};

	struct i2c_gd32_data {
	struct k_sem bus_mutex;
	struct k_sem sync_sem;
	uint32_t dev_config;
	uint16_t addr1;
	uint16_t addr2;
	uint32_t xfer_len;
	struct i2c_msg *current;
	uint8_t errs;
	bool is_stopped;
	bool is_restart;
	};

	static inline void i2c_gd32_enable_interrupts(const struct i2c_gd32_config *cfg)
	{
	I2C_CTL1(cfg->reg) \|= I2C_CTL1_ERRIE;
	I2C_CTL1(cfg->reg) \|= I2C_CTL1_EVIE;
	I2C_CTL1(cfg->reg) \|= I2C_CTL1_BUFIE;
	}

	static inline void i2c_gd32_disable_interrupts(const struct i2c_gd32_config *cfg)
	{
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_ERRIE;
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_EVIE;
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
	}

	static inline void i2c_gd32_xfer_read(struct i2c_gd32_data *data,
	const struct i2c_gd32_config *cfg)
	{
	data->current->len--;
	*data->current->buf = I2C_DATA(cfg->reg);
	data->current->buf++;

	if ((data->xfer_len > 0U) &&
	(data->current->len == 0U)) {
	data->current++;
	}
	}

	static inline void i2c_gd32_xfer_write(struct i2c_gd32_data *data,
	const struct i2c_gd32_config *cfg)
	{
	data->current->len--;
	I2C_DATA(cfg->reg) = *data->current->buf;
	data->current->buf++;

	if ((data->xfer_len > 0U) &&
	(data->current->len == 0U)) {
	data->current++;
	}
	}

	static void i2c_gd32_handle_rbne(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	switch (data->xfer_len) {
	case 0:
	/* Unwanted data received, ignore it. */
	k_sem_give(&data->sync_sem);
	break;
	case 1:
	/* If total_read_length == 1, read the data directly. */
	data->xfer_len--;
	i2c_gd32_xfer_read(data, cfg);

	k_sem_give(&data->sync_sem);

	break;
	case 2:
	__fallthrough;
	case 3:
	/*
	* If total_read_length == 2, or total_read_length > 3
	* and remaining_read_length == 3, disable the RBNE
	* interrupt.
	* Remaining data will be read from BTC interrupt.
	*/
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
	break;
	default:
	/*
	* If total_read_length > 3 and remaining_read_length > 3,
	* read the data directly.
	*/
	data->xfer_len--;
	i2c_gd32_xfer_read(data, cfg);
	break;
	}

	}

	static void i2c_gd32_handle_tbe(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	if (data->xfer_len > 0U) {
	data->xfer_len--;
	if (data->xfer_len == 0U) {
	/*
	* This is the last data to transmit, disable the TBE interrupt.
	* Use the BTC interrupt to indicate the write data complete state.
	*/
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_BUFIE;
	}
	i2c_gd32_xfer_write(data, cfg);

	} else {
	if ((data->current->flags & I2C_MSG_STOP) &&
	(data->is_stopped == false)) {
	data->is_stopped = true;
	/* Enter stop condition */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_STOP;
	}

	if (I2C_STAT0(cfg->reg) & I2C_STAT0_BTC) {
	/* Clear BTC bit */
	I2C_DATA(cfg->reg);
	}

	k_sem_give(&data->sync_sem);
	}
	}

	static void i2c_gd32_handle_btc(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	if (data->current->flags & I2C_MSG_READ) {
	uint32_t counter = 0U;

	switch (data->xfer_len) {
	case 2:
	/*
	* Stop condition must be generated before reading the
	* last two bytes.
	*/
	if ((data->current->flags & I2C_MSG_STOP) &&
	(data->is_stopped == false)) {
	data->is_stopped = true;
	/* Enter stop condition */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_STOP;
	}

	for (counter = 2U; counter > 0; counter--) {
	data->xfer_len--;
	i2c_gd32_xfer_read(data, cfg);
	}

	k_sem_give(&data->sync_sem);

	break;
	case 3:
	/* Clear ACKEN bit */
	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_ACKEN;

	data->xfer_len--;
	i2c_gd32_xfer_read(data, cfg);

	break;
	default:
	i2c_gd32_handle_rbne(dev);
	break;
	}
	} else {
	i2c_gd32_handle_tbe(dev);
	}
	}

	static void i2c_gd32_handle_addsend(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	if (data->is_restart) {
	/* Clear ADDSEND bit */
	I2C_STAT1(cfg->reg);

	data->is_restart = false;
	data->current->flags &= ~I2C_MSG_RW_MASK;
	data->current->flags \|= I2C_MSG_READ;
	/* Enter repeated start condition */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_START;

	return;
	}

	if ((data->current->flags & I2C_MSG_READ) &&
	(data->xfer_len <= 2U)) {
	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_ACKEN;
	}

	/* Clear ADDSEND bit */
	I2C_STAT1(cfg->reg);

	if ((data->xfer_len == 1U) &&
	(data->current->flags & I2C_MSG_STOP) &&
	(data->current->flags & I2C_MSG_READ)) {
	data->is_stopped = true;
	/* Enter stop condition */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_STOP;
	}

	}

	static void i2c_gd32_event_isr(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;
	uint32_t stat;

	stat = I2C_STAT0(cfg->reg);

	if (stat & I2C_STAT0_SBSEND) {
	if (data->current->flags & I2C_MSG_READ) {
	I2C_DATA(cfg->reg) = (data->addr1 << 1U) \| 1U;
	} else {
	I2C_DATA(cfg->reg) = (data->addr1 << 1U) \| 0U;
	}
	} else if (stat & I2C_STAT0_ADD10SEND) {
	I2C_DATA(cfg->reg) = data->addr2;
	} else if (stat & I2C_STAT0_ADDSEND) {
	i2c_gd32_handle_addsend(dev);
	} else if (stat & I2C_STAT0_BTC) {
	i2c_gd32_handle_btc(dev);
	} else if (stat & I2C_STAT0_RBNE) {
	i2c_gd32_handle_rbne(dev);
	} else if (stat & I2C_STAT0_TBE) {
	i2c_gd32_handle_tbe(dev);
	}
	}

	static void i2c_gd32_error_isr(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;
	uint32_t stat;

	stat = I2C_STAT0(cfg->reg);

	if (stat & I2C_STAT0_BERR) {
	I2C_STAT0(cfg->reg) &= ~I2C_STAT0_BERR;
	data->errs \|= I2C_GD32_ERR_BERR;
	}

	if (stat & I2C_STAT0_LOSTARB) {
	I2C_STAT0(cfg->reg) &= ~I2C_STAT0_LOSTARB;
	data->errs \|= I2C_GD32_ERR_LARB;
	}

	if (stat & I2C_STAT0_AERR) {
	I2C_STAT0(cfg->reg) &= ~I2C_STAT0_AERR;
	data->errs \|= I2C_GD32_ERR_AERR;
	}

	if (data->errs != 0U) {
	k_sem_give(&data->sync_sem);
	}
	}

	static void i2c_gd32_log_err(struct i2c_gd32_data *data)
	{
	if (data->errs & I2C_GD32_ERR_BERR) {
	LOG_ERR("Bus error");
	}

	if (data->errs & I2C_GD32_ERR_LARB) {
	LOG_ERR("Arbitration lost");
	}

	if (data->errs & I2C_GD32_ERR_AERR) {
	LOG_ERR("No ACK received");
	}
	}

	static void i2c_gd32_xfer_begin(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	k_sem_reset(&data->sync_sem);

	data->errs = 0U;
	data->is_restart = false;
	data->is_stopped = false;

	/* Enable i2c device */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_I2CEN;

	if (data->current->flags & I2C_MSG_READ) {
	/* Default to set ACKEN bit. */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_ACKEN;

	/* For 2 bytes read, use POAP bit to give NACK for the last data receiving. */
	if (data->xfer_len == 2U) {
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_POAP;
	}

	/*
	* For read on 10 bits address mode, start condition will happen twice.
	* Transfer sequence as below:
	* S addr1+W addr2 S addr1+R
	* Use a is_restart flag to cover this case.
	*/
	if (data->dev_config & I2C_ADDR_10_BITS) {
	data->is_restart = true;
	data->current->flags &= ~I2C_MSG_RW_MASK;
	}
	}

	/* Enter repeated start condition */
	I2C_CTL0(cfg->reg) \|= I2C_CTL0_START;
	}

	static int i2c_gd32_xfer_end(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	i2c_gd32_disable_interrupts(cfg);

	if (data->errs != 0U) {
	/* Disable i2c device */
	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;
	i2c_gd32_log_err(data);
	data->errs = 0U;

	return -EIO;
	}

	if (data->current->flags & I2C_MSG_STOP) {
	/* Wait for stop condition is done. */
	while (I2C_STAT1(cfg->reg) & I2C_STAT1_I2CBSY) {
	/* NOP */
	}
	/* Disable I2C device */
	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;
	}

	return 0;
	}

	static int i2c_gd32_msg_read(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	i2c_gd32_xfer_begin(dev);

	/* For repeated start condition, wait for TBE cleared. */
	while (I2C_STAT0(cfg->reg) & I2C_STAT0_TBE) {
	/* NOP */
	}

	i2c_gd32_enable_interrupts(cfg);

	k_sem_take(&data->sync_sem, K_FOREVER);

	return i2c_gd32_xfer_end(dev);
	}

	static int i2c_gd32_msg_write(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;

	i2c_gd32_xfer_begin(dev);

	/* For repeated start condition, wait for RBNE cleared. */
	while (I2C_STAT0(cfg->reg) & I2C_STAT0_RBNE) {
	/* NOP */
	}

	i2c_gd32_enable_interrupts(cfg);

	k_sem_take(&data->sync_sem, K_FOREVER);

	return i2c_gd32_xfer_end(dev);
	}

	static int i2c_gd32_transfer(const struct device *dev,
	struct i2c_msg *msgs,
	uint8_t num_msgs,
	uint16_t addr)
	{
	struct i2c_gd32_data *data = dev->data;
	struct i2c_msg current, next;
	uint8_t itr;
	int err = 0;

	current = msgs;

	/* First message flags implicitly contain I2C_MSG_RESTART flag. */
	current->flags \|= I2C_MSG_RESTART;

	for (uint8_t i = 1; i <= num_msgs; i++) {

	if (i < num_msgs) {
	next = current + 1;

	/*
	* If there have a R/W transfer state change between messages,
	* An explicit I2C_MSG_RESTART flag is needed for the second message.
	*/
	if ((current->flags & I2C_MSG_RW_MASK) !=
	(next->flags & I2C_MSG_RW_MASK)) {
	if ((next->flags & I2C_MSG_RESTART) == 0U) {
	return -EINVAL;
	}
	}

	/* Only the last message need I2C_MSG_STOP flag to free the Bus. */
	if (current->flags & I2C_MSG_STOP) {
	return -EINVAL;
	}
	} else {
	/* Last message flags implicitly contain I2C_MSG_STOP flag. */
	current->flags \|= I2C_MSG_STOP;
	}

	if ((current->buf == NULL) \|\|
	(current->len == 0U)) {
	return -EINVAL;
	}

	current++;
	}

	k_sem_take(&data->bus_mutex, K_FOREVER);

	if (data->dev_config & I2C_ADDR_10_BITS) {
	data->addr1 = 0xF0 \| ((addr & BITS(8, 9)) >> 8U);
	data->addr2 = addr & BITS(0, 7);
	} else {
	data->addr1 = addr & BITS(0, 6);
	}

	for (uint8_t i = 0; i < num_msgs; i = itr) {
	data->current = &msgs[i];
	data->xfer_len = msgs[i].len;

	for (itr = i + 1; itr < num_msgs; itr++) {
	if ((data->current->flags & I2C_MSG_RW_MASK) !=
	(msgs[itr].flags & I2C_MSG_RW_MASK)) {
	break;
	}
	data->xfer_len += msgs[itr].len;
	}

	if (data->current->flags & I2C_MSG_READ) {
	err = i2c_gd32_msg_read(dev);
	} else {
	err = i2c_gd32_msg_write(dev);
	}

	if (err < 0) {
	break;
	}
	}

	k_sem_give(&data->bus_mutex);

	return err;
	}

	static int i2c_gd32_configure(const struct device *dev,
	uint32_t dev_config)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;
	uint32_t pclk1, freq, clkc;
	int err = 0;

	k_sem_take(&data->bus_mutex, K_FOREVER);

	/* Disable I2C device */
	I2C_CTL0(cfg->reg) &= ~I2C_CTL0_I2CEN;

	/* GD32 i2c interface always connect to APB1. */
	pclk1 = rcu_clock_freq_get(CK_APB1);

	/* i2c clock frequency, us */
	freq = pclk1 / 1000000U;
	if (freq > I2CCLK_MAX) {
	LOG_ERR("I2C max clock freq %u, current is %u\n",
	I2CCLK_MAX, freq);
	err = -ENOTSUP;
	goto error;
	}

	/*
	* Refer from SoC user manual.
	* In standard mode:
	* T_high = CLKC * T_pclk1
	* T_low = CLKC * T_pclk1
	*
	* In fast mode and fast mode plus with DTCY=1:
	* T_high = 9 * CLKC * T_pclk1
	* T_low = 16 * CLKC * T_pclk1
	*
	* T_pclk1 is reciprocal of pclk1:
	* T_pclk1 = 1 / pclk1
	*
	* T_high and T_low construct the bit transfer:
	* T_high + T_low = 1 / bitrate
	*
	* And then, we can get the CLKC equation.
	* Standard mode:
	* CLKC = pclk1 / (bitrate * 2)
	* Fast mode and fast mode plus:
	* CLKC = pclk1 / (bitrate * 25)
	*
	* Variable list:
	* T_high: high period of the SCL clock
	* T_low: low period of the SCL clock
	* T_pclk1: duration of single pclk1 pulse
	* pclk1: i2c device clock frequency
	* bitrate: 100 Kbits for standard mode
	*/
	switch (I2C_SPEED_GET(dev_config)) {
	case I2C_SPEED_STANDARD:
	if (freq < I2CCLK_MIN) {
	LOG_ERR("I2C standard-mode min clock freq %u, current is %u\n",
	I2CCLK_MIN, freq);
	err = -ENOTSUP;
	goto error;
	}
	I2C_CTL1(cfg->reg) &= ~I2C_CTL1_I2CCLK;
	I2C_CTL1(cfg->reg) \|= freq;

	/* Standard-mode risetime maximum value: 1000ns */
	if (freq == I2CCLK_MAX) {
	I2C_RT(cfg->reg) = I2CCLK_MAX;
	} else {
	I2C_RT(cfg->reg) = freq + 1U;
	}

	/* CLKC = pclk1 / (bitrate * 2) */
	clkc = pclk1 / (I2C_BITRATE_STANDARD * 2U);

	I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
	I2C_CKCFG(cfg->reg) \|= clkc;
	/* standard-mode */
	I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_FAST;

	break;
	case I2C_SPEED_FAST:
	if (freq < I2CCLK_FM_MIN) {
	LOG_ERR("I2C fast-mode min clock freq %u, current is %u\n",
	I2CCLK_FM_MIN, freq);
	err = -ENOTSUP;
	goto error;
	}

	/* Fast-mode risetime maximum value: 300ns */
	I2C_RT(cfg->reg) = freq * 300U / 1000U + 1U;

	/* CLKC = pclk1 / (bitrate * 25) */
	clkc = pclk1 / (I2C_BITRATE_FAST_PLUS * 25U);
	if (clkc == 0U) {
	clkc = 1U;
	}

	/* Default DCTY to 1 */
	I2C_CKCFG(cfg->reg) \|= I2C_CKCFG_DTCY;
	I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
	I2C_CKCFG(cfg->reg) \|= clkc;
	/* Transfer mode: fast-mode */
	I2C_CKCFG(cfg->reg) \|= I2C_CKCFG_FAST;

	#ifdef I2C_FMPCFG
	/* Disable transfer mode: fast-mode plus */
	I2C_FMPCFG(cfg->reg) &= ~I2C_FMPCFG_FMPEN;
	#endif /* I2C_FMPCFG */

	break;
	#ifdef I2C_FMPCFG
	case I2C_SPEED_FAST_PLUS:
	if (freq < I2CCLK_FM_PLUS_MIN) {
	LOG_ERR("I2C fast-mode plus min clock freq %u, current is %u\n",
	I2CCLK_FM_PLUS_MIN, freq);
	err = -ENOTSUP;
	goto error;
	}

	/* Fast-mode plus risetime maximum value: 120ns */
	I2C_RT(cfg->reg) = freq * 120U / 1000U + 1U;

	/* CLKC = pclk1 / (bitrate * 25) */
	clkc = pclk1 / (I2C_BITRATE_FAST_PLUS * 25U);
	if (clkc == 0U) {
	clkc = 1U;
	}

	/* Default DCTY to 1 */
	I2C_CKCFG(cfg->reg) \|= I2C_CKCFG_DTCY;
	I2C_CKCFG(cfg->reg) &= ~I2C_CKCFG_CLKC;
	I2C_CKCFG(cfg->reg) \|= clkc;
	/* Transfer mode: fast-mode */
	I2C_CKCFG(cfg->reg) \|= I2C_CKCFG_FAST;

	/* Enable transfer mode: fast-mode plus */
	I2C_FMPCFG(cfg->reg) \|= I2C_FMPCFG_FMPEN;

	break;
	#endif /* I2C_FMPCFG */
	default:
	err = -EINVAL;
	goto error;
	}

	data->dev_config = dev_config;
	error:
	k_sem_give(&data->bus_mutex);

	return err;
	}

	static struct i2c_driver_api i2c_gd32_driver_api = {
	.configure = i2c_gd32_configure,
	.transfer = i2c_gd32_transfer,
	};

	static int i2c_gd32_init(const struct device *dev)
	{
	struct i2c_gd32_data *data = dev->data;
	const struct i2c_gd32_config *cfg = dev->config;
	uint32_t bitrate_cfg;
	int err;

	err = pinctrl_apply_state(cfg->pcfg, PINCTRL_STATE_DEFAULT);
	if (err < 0) {
	return err;
	}

	/* Mutex semaphore to protect the i2c api in multi-thread env. */
	k_sem_init(&data->bus_mutex, 1, 1);

	/* Sync semaphore to sync i2c state between isr and transfer api. */
	k_sem_init(&data->sync_sem, 0, K_SEM_MAX_LIMIT);

	rcu_periph_clock_enable(cfg->rcu_periph_clock);

	cfg->irq_cfg_func();

	bitrate_cfg = i2c_map_dt_bitrate(cfg->bitrate);

	i2c_gd32_configure(dev, I2C_MODE_MASTER \| bitrate_cfg);

	return 0;
	}

	#define I2C_GD32_INIT(inst) \
	PINCTRL_DT_INST_DEFINE(inst); \
	static void i2c_gd32_irq_cfg_func_##inst(void) \
	{ \
	IRQ_CONNECT(DT_INST_IRQ_BY_NAME(inst, event, irq), \
	DT_INST_IRQ_BY_NAME(inst, event, priority), \
	i2c_gd32_event_isr, \
	DEVICE_DT_INST_GET(inst), \
	0); \
	irq_enable(DT_INST_IRQ_BY_NAME(inst, event, irq)); \
	\
	IRQ_CONNECT(DT_INST_IRQ_BY_NAME(inst, error, irq), \
	DT_INST_IRQ_BY_NAME(inst, error, priority), \
	i2c_gd32_error_isr, \
	DEVICE_DT_INST_GET(inst), \
	0); \
	irq_enable(DT_INST_IRQ_BY_NAME(inst, error, irq)); \
	} \
	static struct i2c_gd32_data i2c_gd32_data_##inst; \
	const static struct i2c_gd32_config i2c_gd32_cfg_##inst = { \
	.reg = DT_INST_REG_ADDR(inst), \
	.bitrate = DT_INST_PROP(inst, clock_frequency), \
	.rcu_periph_clock = DT_INST_PROP(inst, rcu_periph_clock), \
	.pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(inst), \
	.irq_cfg_func = i2c_gd32_irq_cfg_func_##inst, \
	}; \
	I2C_DEVICE_DT_INST_DEFINE(inst, \
	i2c_gd32_init, NULL, \
	&i2c_gd32_data_##inst, &i2c_gd32_cfg_##inst, \
	POST_KERNEL, CONFIG_I2C_INIT_PRIORITY, \
	&i2c_gd32_driver_api); \

	DT_INST_FOREACH_STATUS_OKAY(I2C_GD32_INIT)