drivers/i2c/i2c_esp32.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2017 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /* Include esp-idf headers first to avoid redefining BIT() macro */
 #include <soc/dport_reg.h>
 #include <soc/i2c_reg.h>
 #include <rom/gpio.h>
 #include <soc/gpio_sig_map.h>

 #include <soc.h>
 #include <errno.h>
 #include <gpio.h>
 #include <i2c.h>
 #include <misc/util.h>
 #include <string.h>

 /* Number of entries in hardware command queue */
 #define I2C_ESP32_NUM_CMDS 16
 /* Number of bytes in hardware FIFO */
 #define I2C_ESP32_BUFFER_SIZE 32

 #define I2C_ESP32_TIMEOUT_MS 100
 #define I2C_ESP32_SPIN_THRESHOLD 10
 #define I2C_ESP32_YIELD_THRESHOLD (I2C_ESP32_SPIN_THRESHOLD / 2)
 #define I2C_ESP32_TIMEOUT \
 	((I2C_ESP32_YIELD_THRESHOLD) + (I2C_ESP32_SPIN_THRESHOLD))

 enum i2c_esp32_opcodes {
 	I2C_ESP32_OP_RSTART,
 	I2C_ESP32_OP_WRITE,
 	I2C_ESP32_OP_READ,
 	I2C_ESP32_OP_STOP,
 	I2C_ESP32_OP_END
 };

 struct i2c_esp32_cmd {
 	u32_t num_bytes : 8;
 	u32_t ack_en : 1;
 	u32_t ack_exp : 1;
 	u32_t ack_val : 1;
 	u32_t opcode : 3;
 	u32_t reserved : 17;
 	u32_t done : 1;
 };

 struct i2c_esp32_data {
 	u32_t dev_config;
 	u16_t address;

 	struct k_sem fifo_sem;
 	struct k_sem transfer_sem;
 };

 typedef void (*irq_connect_cb)(void);

 struct i2c_esp32_config {
 	int index;

 	irq_connect_cb connect_irq;

 	const struct {
 		int sda_out;
 		int sda_in;
 		int scl_out;
 		int scl_in;
 	} sig;

 	const struct {
 		int scl;
 		int sda;
 	} pins;

 	const struct {
 		int clk;
 		int rst;
 	} enable_bits;

 	const struct {
 		bool tx_lsb_first;
 		bool rx_lsb_first;
 	} mode;

 	const struct {
 		int source;
 		int line;
 	} irq;

 	const u32_t default_config;
 };

 static inline void set_mask32(u32_t v, u32_t mem_addr)
 {
 	sys_write32(sys_read32(mem_addr) | v, mem_addr);
 }

 static inline void clear_mask32(u32_t v, u32_t mem_addr)
 {
 	sys_write32(sys_read32(mem_addr) & ~v, mem_addr);
 }

 static void i2c_esp32_enable_peripheral(const struct i2c_esp32_config *config)
 {
 	set_mask32(config->enable_bits.clk, DPORT_PERIP_CLK_EN_REG);
 	clear_mask32(config->enable_bits.rst, DPORT_PERIP_RST_EN_REG);
 }

 static const char *i2c_esp32_get_gpio_for_pin(int pin)
 {
 	if (pin < 32) {
 #if defined(CONFIG_GPIO_ESP32_0)
 		return CONFIG_GPIO_ESP32_0_NAME;
 #else
 		return NULL;
 #endif /* CONFIG_GPIO_ESP32_0 */
 	}

 #if defined(CONFIG_GPIO_ESP32_1)
 	return CONFIG_GPIO_ESP32_1_NAME;
 #else
 	return NULL;
 #endif /* CONFIG_GPIO_ESP32_1 */
 }

 static int i2c_esp32_configure_pins(int pin, int matrix_out, int matrix_in)
 {
 	const int pin_mode = GPIO_DIR_OUT |
 			     GPIO_DS_DISCONNECT_LOW |
 			     GPIO_PUD_PULL_UP;
 	const char *device_name = i2c_esp32_get_gpio_for_pin(pin);
 	struct device *gpio;
 	int ret;

 	if (!device_name) {
 		return -EINVAL;
 	}
 	gpio = device_get_binding(device_name);
 	if (!gpio) {
 		return -EINVAL;
 	}

 	ret = gpio_pin_configure(gpio, pin, pin_mode);
 	if (ret < 0) {
 		return ret;
 	}

 	ret = gpio_pin_write(gpio, pin, 1);
 	if (ret < 0) {
 		return ret;
 	}

 	esp32_rom_gpio_matrix_out(pin, matrix_out, false, false);
 	esp32_rom_gpio_matrix_in(pin, matrix_in, false);

 	return 0;
 }

 static int i2c_esp32_configure_speed(const struct i2c_esp32_config *config,
 				     u32_t speed)
 {
 	static const u32_t speed_to_freq_tbl[] = {
 		[I2C_SPEED_STANDARD] = KHZ(100),
 		[I2C_SPEED_FAST] = KHZ(400),
 		[I2C_SPEED_FAST_PLUS] = MHZ(1),
 		[I2C_SPEED_HIGH] = 0,
 		[I2C_SPEED_ULTRA] = 0
 	};
 	u32_t freq_hz = speed_to_freq_tbl[speed];
 	u32_t period;

 	if (!freq_hz) {
 		return -ENOTSUP;
 	}

 	period = (APB_CLK_FREQ / freq_hz) / 2;

 	set_mask32(period << I2C_SCL_LOW_PERIOD_S,
 		   I2C_SCL_LOW_PERIOD_REG(config->index));
 	set_mask32(period << I2C_SCL_HIGH_PERIOD_S,
 		   I2C_SCL_HIGH_PERIOD_REG(config->index));

 	period /= 2; /* Set hold and setup times to 1/2th of period */
 	set_mask32(period << I2C_SCL_START_HOLD_TIME_S,
 		   I2C_SCL_START_HOLD_REG(config->index));
 	set_mask32(period << I2C_SCL_RSTART_SETUP_TIME_S,
 		   I2C_SCL_RSTART_SETUP_REG(config->index));
 	set_mask32(period << I2C_SCL_STOP_HOLD_TIME_S,
 		   I2C_SCL_STOP_HOLD_REG(config->index));
 	set_mask32(period << I2C_SCL_STOP_SETUP_TIME_S,
 		   I2C_SCL_STOP_SETUP_REG(config->index));

 	period /= 2; /* Set sample and hold times to 1/4th of period */
 	set_mask32(period << I2C_SDA_HOLD_TIME_S,
 		   I2C_SDA_HOLD_REG(config->index));
 	set_mask32(period << I2C_SDA_SAMPLE_TIME_S,
 		   I2C_SDA_SAMPLE_REG(config->index));

 	return 0;
 }

 static int i2c_esp32_configure(struct device *dev, u32_t dev_config)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	struct i2c_esp32_data *data = dev->driver_data;
 	int key = irq_lock();
 	u32_t v = 0;
 	int ret;

 	ret = i2c_esp32_configure_pins(config->pins.scl,
 				       config->sig.scl_out,
 				       config->sig.scl_in);
 	if (ret < 0) {
 		return ret;
 	}

 	ret = i2c_esp32_configure_pins(config->pins.sda,
 				       config->sig.sda_out,
 				       config->sig.sda_in);
 	if (ret < 0) {
 		return ret;
 	}

 	i2c_esp32_enable_peripheral(config);

 	/* MSB or LSB first is configurable for both TX and RX */
 	if (config->mode.tx_lsb_first) {
 		v |= I2C_TX_LSB_FIRST;
 	}

 	if (config->mode.rx_lsb_first) {
 		v |= I2C_RX_LSB_FIRST;
 	}

 	if (dev_config & I2C_MODE_MASTER) {
 		v |= I2C_MS_MODE;
 		sys_write32(0, I2C_SLAVE_ADDR_REG(config->index));
 	} else {
 		u32_t addr = (data->address & I2C_SLAVE_ADDR_V);

 		if (dev_config & I2C_ADDR_10_BITS) {
 			addr |= I2C_ADDR_10BIT_EN;
 		}
 		sys_write32(addr << I2C_SLAVE_ADDR_S,
 			    I2C_SLAVE_ADDR_REG(config->index));

 		/* Before setting up FIFO and interrupts, stop transmission */
 		sys_clear_bit(I2C_CTR_REG(config->index), I2C_TRANS_START_S);

 		/* Byte after address isn't the offset address in slave RAM */
 		sys_clear_bit(I2C_FIFO_CONF_REG(config->index),
 			      I2C_FIFO_ADDR_CFG_EN_S);
 	}

 	/* Use open-drain for clock and data pins */
 	v |= (I2C_SCL_FORCE_OUT | I2C_SDA_FORCE_OUT);
 	v |= I2C_CLK_EN;
 	sys_write32(v, I2C_CTR_REG(config->index));

 	ret = i2c_esp32_configure_speed(config, I2C_SPEED_GET(dev_config));
 	if (ret < 0) {
 		goto out;
 	}

 	/* Use FIFO to transmit data */
 	sys_clear_bit(I2C_FIFO_CONF_REG(config->index), I2C_NONFIFO_EN_S);

 	v = CONFIG_I2C_ESP32_TIMEOUT & I2C_TIME_OUT_REG;
 	sys_write32(v << I2C_TIME_OUT_REG_S, I2C_TO_REG(config->index));

 	/* Enable interrupt types handled by the ISR */
 	sys_write32(I2C_ACK_ERR_INT_ENA_M |
 		    I2C_TIME_OUT_INT_ENA_M |
 		    I2C_TRANS_COMPLETE_INT_ENA_M |
 		    I2C_ARBITRATION_LOST_INT_ENA_M,
 		    I2C_INT_ENA_REG(config->index));

 	irq_enable(config->irq.line);

 out:
 	irq_unlock(key);

 	return ret;
 }

 static inline void i2c_esp32_reset_fifo(const struct i2c_esp32_config *config)
 {
 	u32_t reg = I2C_FIFO_CONF_REG(config->index);

 	/* Writing 1 and then 0 to these bits will reset the I2C fifo */
 	set_mask32(I2C_TX_FIFO_RST | I2C_RX_FIFO_RST, reg);
 	clear_mask32(I2C_TX_FIFO_RST | I2C_RX_FIFO_RST, reg);
 }

 static int i2c_esp32_spin_yield(int *counter)
 {
 	*counter = *counter + 1;

 	if (*counter > I2C_ESP32_TIMEOUT) {
 		return -ETIMEDOUT;
 	}

 	if (*counter > I2C_ESP32_SPIN_THRESHOLD) {
 		k_yield();
 	}

 	return 0;
 }

 static int i2c_esp32_transmit(struct device *dev)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	struct i2c_esp32_data *data = dev->driver_data;
 	u32_t status;

 	/* Start transmission and wait for the ISR to give the semaphore */
 	sys_set_bit(I2C_CTR_REG(config->index), I2C_TRANS_START_S);
 	if (k_sem_take(&data->fifo_sem, I2C_ESP32_TIMEOUT_MS) < 0) {
 		return -ETIMEDOUT;
 	}

 	status = sys_read32(I2C_INT_RAW_REG(config->index));
 	if (status & (I2C_ARBITRATION_LOST_INT_RAW | I2C_ACK_ERR_INT_RAW)) {
 		return -EIO;
 	}
 	if (status & I2C_TIME_OUT_INT_RAW) {
 		return -ETIMEDOUT;
 	}

 	return 0;
 }

 static int i2c_esp32_wait(struct device *dev,
 			  volatile struct i2c_esp32_cmd *wait_cmd)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	int counter = 0;
 	int ret;

 	if (wait_cmd) {
 		while (!wait_cmd->done) {
 			ret = i2c_esp32_spin_yield(&counter);
 			if (ret < 0) {
 				return ret;
 			}
 		}
 	}

 	/* Wait for I2C bus to finish its business */
 	while (sys_read32(I2C_INT_STATUS_REG(config->index)) & I2C_BUS_BUSY) {
 		ret = i2c_esp32_spin_yield(&counter);
 		if (ret < 0) {
 			return ret;
 		}
 	}

 	return 0;
 }

 static int i2c_esp32_transmit_wait(struct device *dev,
 				   volatile struct i2c_esp32_cmd *wait_cmd)
 {
 	int ret;

 	ret = i2c_esp32_transmit(dev);
 	if (!ret) {
 		return i2c_esp32_wait(dev, wait_cmd);
 	}

 	return ret;
 }

 static volatile struct i2c_esp32_cmd *
 i2c_esp32_write_addr(struct device *dev,
 		     volatile struct i2c_esp32_cmd *cmd,
 		     struct i2c_msg *msg,
 		     u16_t addr)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	struct i2c_esp32_data *data = dev->driver_data;
 	u32_t addr_len = 1;

 	i2c_esp32_reset_fifo(config);

 	sys_write32(addr & I2C_FIFO_RDATA, I2C_DATA_APB_REG(config->index));
 	if (data->dev_config & I2C_ADDR_10_BITS) {
 		sys_write32(I2C_DATA_APB_REG(config->index),
 			    (addr >> 8) & I2C_FIFO_RDATA);
 		addr_len++;
 	}

 	*cmd++ = (struct i2c_esp32_cmd) {
 		.opcode = I2C_ESP32_OP_WRITE,
 		.ack_en = true,
 		.num_bytes = addr_len,
 	};

 	msg->len += addr_len;

 	return cmd;
 }

 static int i2c_esp32_read_msg(struct device *dev, u16_t addr,
 			      struct i2c_msg msg)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	volatile struct i2c_esp32_cmd *cmd =
 		(void *)I2C_COMD0_REG(config->index);
 	u32_t i;
 	int ret;

 	/* Set the R/W bit to R */
 	addr |= BIT(0);

 	if (msg.flags & I2C_MSG_RESTART) {
 		*cmd++ = (struct i2c_esp32_cmd) {
 			.opcode = I2C_ESP32_OP_RSTART
 		};
 	}

 	cmd = i2c_esp32_write_addr(dev, cmd, &msg, addr);

 	for (; msg.len; cmd = (void *)I2C_COMD0_REG(config->index)) {
 		volatile struct i2c_esp32_cmd *wait_cmd = NULL;
 		u32_t to_read = max(I2C_ESP32_BUFFER_SIZE, msg.len - 1);

 		/* Might be the last byte, in which case, `to_read` will
 		 * be 0 here.  See comment below.
 		 */
 		if (to_read) {
 			*cmd++ = (struct i2c_esp32_cmd) {
 				.opcode = I2C_ESP32_OP_READ,
 				.num_bytes = to_read,
 			};
 		}

 		/* I2C master won't acknowledge the last byte read from the
 		 * slave device.  Divide the read command in two segments as
 		 * recommended by the ESP32 Technical Reference Manual.
 		 */
 		if (msg.len - to_read <= 1) {
 			/* Read the last byte and explicitly ask for an
 			 * acknowledgment.
 			 */
 			*cmd++ = (struct i2c_esp32_cmd) {
 				.opcode = I2C_ESP32_OP_READ,
 				.num_bytes = 1,
 				.ack_val = true,
 			};

 			/* Account for the `msg.len - 1` when clamping
 			 * transmission length to FIFO buffer size.
 			 */
 			to_read++;

 			if (msg.flags & I2C_MSG_STOP) {
 				wait_cmd = cmd;
 				*cmd++ = (struct i2c_esp32_cmd) {
 					.opcode = I2C_ESP32_OP_STOP
 				};
 			}
 		}
 		if (!wait_cmd) {
 			*cmd++ = (struct i2c_esp32_cmd) {
 				.opcode = I2C_ESP32_OP_END
 			};
 		}

 		ret = i2c_esp32_transmit_wait(dev, wait_cmd);
 		if (ret < 0) {
 			return ret;
 		}

 		for (i = 0; i < to_read; i++) {
 			u32_t v = sys_read32(I2C_DATA_APB_REG(config->index));

 			*msg.buf++ = v & I2C_FIFO_RDATA;
 		}
 		msg.len -= to_read;

 		i2c_esp32_reset_fifo(config);
 	}

 	return 0;
 }

 static int i2c_esp32_write_msg(struct device *dev, u16_t addr,
 			       struct i2c_msg msg)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	volatile struct i2c_esp32_cmd *cmd =
 		(void *)I2C_COMD0_REG(config->index);

 	if (msg.flags & I2C_MSG_RESTART) {
 		*cmd++ = (struct i2c_esp32_cmd) {
 			.opcode = I2C_ESP32_OP_RSTART
 		};
 	}

 	cmd = i2c_esp32_write_addr(dev, cmd, &msg, addr);

 	for (; msg.len; cmd = (void *)I2C_COMD0_REG(config->index)) {
 		volatile struct i2c_esp32_cmd *wait_cmd = cmd;
 		u32_t to_send = min(I2C_ESP32_BUFFER_SIZE, msg.len);
 		u32_t i;
 		int ret;

 		/* Copy data to TX fifo */
 		for (i = 0; i < to_send; i++) {
 			sys_write32(*msg.buf++,
 				    I2C_DATA_APB_REG(config->index));
 		}
 		*cmd++ = (struct i2c_esp32_cmd) {
 			.opcode = I2C_ESP32_OP_WRITE,
 			.num_bytes = to_send,
 			.ack_en = true,
 		};
 		msg.len -= to_send;

 		if (!msg.len && (msg.flags & I2C_MSG_STOP)) {
 			*cmd++ = (struct i2c_esp32_cmd) {
 				.opcode = I2C_ESP32_OP_STOP
 			};
 		}
 		*cmd++ = (struct i2c_esp32_cmd) {
 			.opcode = I2C_ESP32_OP_END
 		};

 		ret = i2c_esp32_transmit_wait(dev, wait_cmd);
 		if (ret < 0) {
 			return ret;
 		}

 		i2c_esp32_reset_fifo(config);
 	}

 	return 0;
 }

 static int i2c_esp32_transfer(struct device *dev, struct i2c_msg *msgs,
 			      u8_t num_msgs, u16_t addr)
 {
 	struct i2c_esp32_data *data = dev->driver_data;
 	int ret = 0;
 	u8_t i;

 	k_sem_take(&data->transfer_sem, K_FOREVER);

 	/* Mask out unused address bits, and make room for R/W bit */
 	addr &= BIT_MASK(data->dev_config & I2C_ADDR_10_BITS ? 10 : 7);
 	addr <<= 1;

 	for (i = 0; i < num_msgs; i++) {
 		if ((msgs[i].flags & I2C_MSG_RW_MASK) == I2C_MSG_WRITE) {
 			ret = i2c_esp32_write_msg(dev, addr, msgs[i]);
 		} else {
 			ret = i2c_esp32_read_msg(dev, addr, msgs[i]);
 		}

 		if (ret < 0) {
 			break;
 		}
 	}

 	k_sem_give(&data->transfer_sem);

 	return ret;
 }

 static void i2c_esp32_isr(void *arg)
 {
 	const int fifo_give_mask = I2C_ACK_ERR_INT_ST |
 				   I2C_TIME_OUT_INT_ST |
 				   I2C_TRANS_COMPLETE_INT_ST |
 				   I2C_ARBITRATION_LOST_INT_ST;
 	struct device *device = arg;
 	const struct i2c_esp32_config *config = device->config->config_info;

 	if (sys_read32(I2C_INT_STATUS_REG(config->index)) & fifo_give_mask) {
 		struct i2c_esp32_data *data = device->driver_data;

 		/* Only give the semaphore if a watched interrupt happens.
 		 * Error checking is performed at the other side of the
 		 * semaphore, by reading the status register.
 		 */
 		k_sem_give(&data->fifo_sem);
 	}

 	/* Acknowledge all I2C interrupts */
 	sys_write32(~0, I2C_INT_CLR_REG(config->index));
 }

 static int i2c_esp32_init(struct device *dev);

 static const struct i2c_driver_api i2c_esp32_driver_api = {
 	.configure = i2c_esp32_configure,
 	.transfer = i2c_esp32_transfer,
 };

 #ifdef CONFIG_I2C_0
 DEVICE_DECLARE(i2c_esp32_0);

 static void i2c_esp32_connect_irq_0(void)
 {
 	IRQ_CONNECT(CONFIG_I2C_ESP32_0_IRQ, 1, i2c_esp32_isr,
 		    DEVICE_GET(i2c_esp32_0), 0);
 }

 static const struct i2c_esp32_config i2c_esp32_config_0 = {
 	.index = 0,
 	.connect_irq = i2c_esp32_connect_irq_0,
 	.sig = {
 		.sda_out = I2CEXT0_SDA_OUT_IDX,
 		.sda_in = I2CEXT0_SDA_IN_IDX,
 		.scl_out = I2CEXT0_SCL_OUT_IDX,
 		.scl_in = I2CEXT0_SCL_IN_IDX,
 	},
 	.pins = {
 		.scl = CONFIG_I2C_ESP32_0_SCL_PIN,
 		.sda = CONFIG_I2C_ESP32_0_SDA_PIN,
 	},
 	.enable_bits = {
 		.clk = DPORT_I2C_EXT0_CLK_EN,
 		.rst = DPORT_I2C_EXT0_RST,
 	},
 	.mode = {
 		.tx_lsb_first =
 			IS_ENABLED(CONFIG_ESP32_I2C_0_TX_LSB_FIRST),
 		.rx_lsb_first =
 			IS_ENABLED(CONFIG_ESP32_I2C_0_RX_LSB_FIRST),
 	},
 	.irq = {
 		.source = ETS_I2C_EXT0_INTR_SOURCE,
 		.line = CONFIG_I2C_ESP32_0_IRQ,
 	},
 	.default_config = CONFIG_I2C_0_DEFAULT_CFG,
 };

 static struct i2c_esp32_data i2c_esp32_data_0;

 DEVICE_AND_API_INIT(i2c_esp32_0, CONFIG_I2C_0_NAME, &i2c_esp32_init,
 		    &i2c_esp32_data_0, &i2c_esp32_config_0,
 		    POST_KERNEL, CONFIG_I2C_INIT_PRIORITY,
 		    &i2c_esp32_driver_api);
 #endif /* CONFIG_I2C_0 */

 #ifdef CONFIG_I2C_1
 DEVICE_DECLARE(i2c_esp32_1);

 static void i2c_esp32_connect_irq_1(void)
 {
 	IRQ_CONNECT(CONFIG_I2C_ESP32_0_IRQ, 1, i2c_esp32_isr,
 		    DEVICE_GET(i2c_esp32_1), 0);
 }

 static const struct i2c_esp32_config i2c_esp32_config_1 = {
 	.index = 1,
 	.connect_irq = i2c_esp32_connect_irq_1,
 	.sig = {
 		.sda_out = I2CEXT1_SDA_OUT_IDX,
 		.sda_in = I2CEXT1_SDA_IN_IDX,
 		.scl_out = I2CEXT1_SCL_OUT_IDX,
 		.scl_in = I2CEXT1_SCL_IN_IDX,
 	},
 	.pins = {
 		.scl = CONFIG_I2C_ESP32_1_SCL_PIN,
 		.sda = CONFIG_I2C_ESP32_1_SDA_PIN,
 	},
 	.enable_bits = {
 		.clk = DPORT_I2C_EXT1_CLK_EN,
 		.rst = DPORT_I2C_EXT1_RST,
 	},
 	.mode = {
 		.tx_lsb_first =
 			IS_ENABLED(CONFIG_ESP32_I2C_1_TX_LSB_FIRST),
 		.rx_lsb_first =
 			IS_ENABLED(CONFIG_ESP32_I2C_1_RX_LSB_FIRST),
 	},
 	.irq = {
 		.source = ETS_I2C_EXT1_INTR_SOURCE,
 		.line = CONFIG_I2C_ESP32_1_IRQ,
 	},
 	.default_config = CONFIG_I2C_1_DEFAULT_CFG,
 };

 static struct i2c_esp32_data i2c_esp32_data_1;

 DEVICE_AND_API_INIT(i2c_esp32_1, CONFIG_I2C_1_NAME, &i2c_esp32_init,
 		    &i2c_esp32_data_1, &i2c_esp32_config_1,
 		    POST_KERNEL, CONFIG_I2C_INIT_PRIORITY,
 		    &i2c_esp32_driver_api);
 #endif /* CONFIG_I2C_1 */

 static int i2c_esp32_init(struct device *dev)
 {
 	const struct i2c_esp32_config *config = dev->config->config_info;
 	struct i2c_esp32_data *data = dev->driver_data;
 	int key = irq_lock();

 	k_sem_init(&data->fifo_sem, 1, 1);
 	k_sem_init(&data->transfer_sem, 1, 1);

 	irq_disable(config->irq.line);

 	/* Even if irq_enable() is called on config->irq.line, disable
 	 * interrupt sources in the I2C controller.
 	 */
 	sys_write32(0, I2C_INT_ENA_REG(config->index));
 	esp32_rom_intr_matrix_set(0, config->irq.source, config->irq.line);

 	config->connect_irq();
 	irq_unlock(key);

 	return i2c_esp32_configure(dev, config->default_config);
 }
	/*
	* Copyright (c) 2017 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/* Include esp-idf headers first to avoid redefining BIT() macro */
	#include <soc/dport_reg.h>
	#include <soc/i2c_reg.h>
	#include <rom/gpio.h>
	#include <soc/gpio_sig_map.h>

	#include <soc.h>
	#include <errno.h>
	#include <gpio.h>
	#include <i2c.h>
	#include <misc/util.h>
	#include <string.h>

	/* Number of entries in hardware command queue */
	#define I2C_ESP32_NUM_CMDS 16
	/* Number of bytes in hardware FIFO */
	#define I2C_ESP32_BUFFER_SIZE 32

	#define I2C_ESP32_TIMEOUT_MS 100
	#define I2C_ESP32_SPIN_THRESHOLD 10
	#define I2C_ESP32_YIELD_THRESHOLD (I2C_ESP32_SPIN_THRESHOLD / 2)
	#define I2C_ESP32_TIMEOUT \
	((I2C_ESP32_YIELD_THRESHOLD) + (I2C_ESP32_SPIN_THRESHOLD))

	enum i2c_esp32_opcodes {
	I2C_ESP32_OP_RSTART,
	I2C_ESP32_OP_WRITE,
	I2C_ESP32_OP_READ,
	I2C_ESP32_OP_STOP,
	I2C_ESP32_OP_END
	};

	struct i2c_esp32_cmd {
	u32_t num_bytes : 8;
	u32_t ack_en : 1;
	u32_t ack_exp : 1;
	u32_t ack_val : 1;
	u32_t opcode : 3;
	u32_t reserved : 17;
	u32_t done : 1;
	};

	struct i2c_esp32_data {
	u32_t dev_config;
	u16_t address;

	struct k_sem fifo_sem;
	struct k_sem transfer_sem;
	};

	typedef void (*irq_connect_cb)(void);

	struct i2c_esp32_config {
	int index;

	irq_connect_cb connect_irq;

	const struct {
	int sda_out;
	int sda_in;
	int scl_out;
	int scl_in;
	} sig;

	const struct {
	int scl;
	int sda;
	} pins;

	const struct {
	int clk;
	int rst;
	} enable_bits;

	const struct {
	bool tx_lsb_first;
	bool rx_lsb_first;
	} mode;

	const struct {
	int source;
	int line;
	} irq;

	const u32_t default_config;
	};

	static inline void set_mask32(u32_t v, u32_t mem_addr)
	{
	sys_write32(sys_read32(mem_addr) \| v, mem_addr);
	}

	static inline void clear_mask32(u32_t v, u32_t mem_addr)
	{
	sys_write32(sys_read32(mem_addr) & ~v, mem_addr);
	}

	static void i2c_esp32_enable_peripheral(const struct i2c_esp32_config *config)
	{
	set_mask32(config->enable_bits.clk, DPORT_PERIP_CLK_EN_REG);
	clear_mask32(config->enable_bits.rst, DPORT_PERIP_RST_EN_REG);
	}

	static const char *i2c_esp32_get_gpio_for_pin(int pin)
	{
	if (pin < 32) {
	#if defined(CONFIG_GPIO_ESP32_0)
	return CONFIG_GPIO_ESP32_0_NAME;
	#else
	return NULL;
	#endif /* CONFIG_GPIO_ESP32_0 */
	}

	#if defined(CONFIG_GPIO_ESP32_1)
	return CONFIG_GPIO_ESP32_1_NAME;
	#else
	return NULL;
	#endif /* CONFIG_GPIO_ESP32_1 */
	}

	static int i2c_esp32_configure_pins(int pin, int matrix_out, int matrix_in)
	{
	const int pin_mode = GPIO_DIR_OUT \|
	GPIO_DS_DISCONNECT_LOW \|
	GPIO_PUD_PULL_UP;
	const char *device_name = i2c_esp32_get_gpio_for_pin(pin);
	struct device *gpio;
	int ret;

	if (!device_name) {
	return -EINVAL;
	}
	gpio = device_get_binding(device_name);
	if (!gpio) {
	return -EINVAL;
	}

	ret = gpio_pin_configure(gpio, pin, pin_mode);
	if (ret < 0) {
	return ret;
	}

	ret = gpio_pin_write(gpio, pin, 1);
	if (ret < 0) {
	return ret;
	}

	esp32_rom_gpio_matrix_out(pin, matrix_out, false, false);
	esp32_rom_gpio_matrix_in(pin, matrix_in, false);

	return 0;
	}

	static int i2c_esp32_configure_speed(const struct i2c_esp32_config *config,
	u32_t speed)
	{
	static const u32_t speed_to_freq_tbl[] = {
	[I2C_SPEED_STANDARD] = KHZ(100),
	[I2C_SPEED_FAST] = KHZ(400),
	[I2C_SPEED_FAST_PLUS] = MHZ(1),
	[I2C_SPEED_HIGH] = 0,
	[I2C_SPEED_ULTRA] = 0
	};
	u32_t freq_hz = speed_to_freq_tbl[speed];
	u32_t period;

	if (!freq_hz) {
	return -ENOTSUP;
	}

	period = (APB_CLK_FREQ / freq_hz) / 2;

	set_mask32(period << I2C_SCL_LOW_PERIOD_S,
	I2C_SCL_LOW_PERIOD_REG(config->index));
	set_mask32(period << I2C_SCL_HIGH_PERIOD_S,
	I2C_SCL_HIGH_PERIOD_REG(config->index));

	period /= 2; /* Set hold and setup times to 1/2th of period */
	set_mask32(period << I2C_SCL_START_HOLD_TIME_S,
	I2C_SCL_START_HOLD_REG(config->index));
	set_mask32(period << I2C_SCL_RSTART_SETUP_TIME_S,
	I2C_SCL_RSTART_SETUP_REG(config->index));
	set_mask32(period << I2C_SCL_STOP_HOLD_TIME_S,
	I2C_SCL_STOP_HOLD_REG(config->index));
	set_mask32(period << I2C_SCL_STOP_SETUP_TIME_S,
	I2C_SCL_STOP_SETUP_REG(config->index));

	period /= 2; /* Set sample and hold times to 1/4th of period */
	set_mask32(period << I2C_SDA_HOLD_TIME_S,
	I2C_SDA_HOLD_REG(config->index));
	set_mask32(period << I2C_SDA_SAMPLE_TIME_S,
	I2C_SDA_SAMPLE_REG(config->index));

	return 0;
	}

	static int i2c_esp32_configure(struct device *dev, u32_t dev_config)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	struct i2c_esp32_data *data = dev->driver_data;
	int key = irq_lock();
	u32_t v = 0;
	int ret;

	ret = i2c_esp32_configure_pins(config->pins.scl,
	config->sig.scl_out,
	config->sig.scl_in);
	if (ret < 0) {
	return ret;
	}

	ret = i2c_esp32_configure_pins(config->pins.sda,
	config->sig.sda_out,
	config->sig.sda_in);
	if (ret < 0) {
	return ret;
	}

	i2c_esp32_enable_peripheral(config);

	/* MSB or LSB first is configurable for both TX and RX */
	if (config->mode.tx_lsb_first) {
	v \|= I2C_TX_LSB_FIRST;
	}

	if (config->mode.rx_lsb_first) {
	v \|= I2C_RX_LSB_FIRST;
	}

	if (dev_config & I2C_MODE_MASTER) {
	v \|= I2C_MS_MODE;
	sys_write32(0, I2C_SLAVE_ADDR_REG(config->index));
	} else {
	u32_t addr = (data->address & I2C_SLAVE_ADDR_V);

	if (dev_config & I2C_ADDR_10_BITS) {
	addr \|= I2C_ADDR_10BIT_EN;
	}
	sys_write32(addr << I2C_SLAVE_ADDR_S,
	I2C_SLAVE_ADDR_REG(config->index));

	/* Before setting up FIFO and interrupts, stop transmission */
	sys_clear_bit(I2C_CTR_REG(config->index), I2C_TRANS_START_S);

	/* Byte after address isn't the offset address in slave RAM */
	sys_clear_bit(I2C_FIFO_CONF_REG(config->index),
	I2C_FIFO_ADDR_CFG_EN_S);
	}

	/* Use open-drain for clock and data pins */
	v \|= (I2C_SCL_FORCE_OUT \| I2C_SDA_FORCE_OUT);
	v \|= I2C_CLK_EN;
	sys_write32(v, I2C_CTR_REG(config->index));

	ret = i2c_esp32_configure_speed(config, I2C_SPEED_GET(dev_config));
	if (ret < 0) {
	goto out;
	}

	/* Use FIFO to transmit data */
	sys_clear_bit(I2C_FIFO_CONF_REG(config->index), I2C_NONFIFO_EN_S);

	v = CONFIG_I2C_ESP32_TIMEOUT & I2C_TIME_OUT_REG;
	sys_write32(v << I2C_TIME_OUT_REG_S, I2C_TO_REG(config->index));

	/* Enable interrupt types handled by the ISR */
	sys_write32(I2C_ACK_ERR_INT_ENA_M \|
	I2C_TIME_OUT_INT_ENA_M \|
	I2C_TRANS_COMPLETE_INT_ENA_M \|
	I2C_ARBITRATION_LOST_INT_ENA_M,
	I2C_INT_ENA_REG(config->index));

	irq_enable(config->irq.line);

	out:
	irq_unlock(key);

	return ret;
	}

	static inline void i2c_esp32_reset_fifo(const struct i2c_esp32_config *config)
	{
	u32_t reg = I2C_FIFO_CONF_REG(config->index);

	/* Writing 1 and then 0 to these bits will reset the I2C fifo */
	set_mask32(I2C_TX_FIFO_RST \| I2C_RX_FIFO_RST, reg);
	clear_mask32(I2C_TX_FIFO_RST \| I2C_RX_FIFO_RST, reg);
	}

	static int i2c_esp32_spin_yield(int *counter)
	{
	counter = counter + 1;

	if (*counter > I2C_ESP32_TIMEOUT) {
	return -ETIMEDOUT;
	}

	if (*counter > I2C_ESP32_SPIN_THRESHOLD) {
	k_yield();
	}

	return 0;
	}

	static int i2c_esp32_transmit(struct device *dev)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	struct i2c_esp32_data *data = dev->driver_data;
	u32_t status;

	/* Start transmission and wait for the ISR to give the semaphore */
	sys_set_bit(I2C_CTR_REG(config->index), I2C_TRANS_START_S);
	if (k_sem_take(&data->fifo_sem, I2C_ESP32_TIMEOUT_MS) < 0) {
	return -ETIMEDOUT;
	}

	status = sys_read32(I2C_INT_RAW_REG(config->index));
	if (status & (I2C_ARBITRATION_LOST_INT_RAW \| I2C_ACK_ERR_INT_RAW)) {
	return -EIO;
	}
	if (status & I2C_TIME_OUT_INT_RAW) {
	return -ETIMEDOUT;
	}

	return 0;
	}

	static int i2c_esp32_wait(struct device *dev,
	volatile struct i2c_esp32_cmd *wait_cmd)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	int counter = 0;
	int ret;

	if (wait_cmd) {
	while (!wait_cmd->done) {
	ret = i2c_esp32_spin_yield(&counter);
	if (ret < 0) {
	return ret;
	}
	}
	}

	/* Wait for I2C bus to finish its business */
	while (sys_read32(I2C_INT_STATUS_REG(config->index)) & I2C_BUS_BUSY) {
	ret = i2c_esp32_spin_yield(&counter);
	if (ret < 0) {
	return ret;
	}
	}

	return 0;
	}

	static int i2c_esp32_transmit_wait(struct device *dev,
	volatile struct i2c_esp32_cmd *wait_cmd)
	{
	int ret;

	ret = i2c_esp32_transmit(dev);
	if (!ret) {
	return i2c_esp32_wait(dev, wait_cmd);
	}

	return ret;
	}

	static volatile struct i2c_esp32_cmd *
	i2c_esp32_write_addr(struct device *dev,
	volatile struct i2c_esp32_cmd *cmd,
	struct i2c_msg *msg,
	u16_t addr)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	struct i2c_esp32_data *data = dev->driver_data;
	u32_t addr_len = 1;

	i2c_esp32_reset_fifo(config);

	sys_write32(addr & I2C_FIFO_RDATA, I2C_DATA_APB_REG(config->index));
	if (data->dev_config & I2C_ADDR_10_BITS) {
	sys_write32(I2C_DATA_APB_REG(config->index),
	(addr >> 8) & I2C_FIFO_RDATA);
	addr_len++;
	}

	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_WRITE,
	.ack_en = true,
	.num_bytes = addr_len,
	};

	msg->len += addr_len;

	return cmd;
	}

	static int i2c_esp32_read_msg(struct device *dev, u16_t addr,
	struct i2c_msg msg)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	volatile struct i2c_esp32_cmd *cmd =
	(void *)I2C_COMD0_REG(config->index);
	u32_t i;
	int ret;

	/* Set the R/W bit to R */
	addr \|= BIT(0);

	if (msg.flags & I2C_MSG_RESTART) {
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_RSTART
	};
	}

	cmd = i2c_esp32_write_addr(dev, cmd, &msg, addr);

	for (; msg.len; cmd = (void *)I2C_COMD0_REG(config->index)) {
	volatile struct i2c_esp32_cmd *wait_cmd = NULL;
	u32_t to_read = max(I2C_ESP32_BUFFER_SIZE, msg.len - 1);

	/* Might be the last byte, in which case, `to_read` will
	* be 0 here. See comment below.
	*/
	if (to_read) {
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_READ,
	.num_bytes = to_read,
	};
	}

	/* I2C master won't acknowledge the last byte read from the
	* slave device. Divide the read command in two segments as
	* recommended by the ESP32 Technical Reference Manual.
	*/
	if (msg.len - to_read <= 1) {
	/* Read the last byte and explicitly ask for an
	* acknowledgment.
	*/
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_READ,
	.num_bytes = 1,
	.ack_val = true,
	};

	/* Account for the `msg.len - 1` when clamping
	* transmission length to FIFO buffer size.
	*/
	to_read++;

	if (msg.flags & I2C_MSG_STOP) {
	wait_cmd = cmd;
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_STOP
	};
	}
	}
	if (!wait_cmd) {
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_END
	};
	}

	ret = i2c_esp32_transmit_wait(dev, wait_cmd);
	if (ret < 0) {
	return ret;
	}

	for (i = 0; i < to_read; i++) {
	u32_t v = sys_read32(I2C_DATA_APB_REG(config->index));

	*msg.buf++ = v & I2C_FIFO_RDATA;
	}
	msg.len -= to_read;

	i2c_esp32_reset_fifo(config);
	}

	return 0;
	}

	static int i2c_esp32_write_msg(struct device *dev, u16_t addr,
	struct i2c_msg msg)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	volatile struct i2c_esp32_cmd *cmd =
	(void *)I2C_COMD0_REG(config->index);

	if (msg.flags & I2C_MSG_RESTART) {
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_RSTART
	};
	}

	cmd = i2c_esp32_write_addr(dev, cmd, &msg, addr);

	for (; msg.len; cmd = (void *)I2C_COMD0_REG(config->index)) {
	volatile struct i2c_esp32_cmd *wait_cmd = cmd;
	u32_t to_send = min(I2C_ESP32_BUFFER_SIZE, msg.len);
	u32_t i;
	int ret;

	/* Copy data to TX fifo */
	for (i = 0; i < to_send; i++) {
	sys_write32(*msg.buf++,
	I2C_DATA_APB_REG(config->index));
	}
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_WRITE,
	.num_bytes = to_send,
	.ack_en = true,
	};
	msg.len -= to_send;

	if (!msg.len && (msg.flags & I2C_MSG_STOP)) {
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_STOP
	};
	}
	*cmd++ = (struct i2c_esp32_cmd) {
	.opcode = I2C_ESP32_OP_END
	};

	ret = i2c_esp32_transmit_wait(dev, wait_cmd);
	if (ret < 0) {
	return ret;
	}

	i2c_esp32_reset_fifo(config);
	}

	return 0;
	}

	static int i2c_esp32_transfer(struct device dev, struct i2c_msg msgs,
	u8_t num_msgs, u16_t addr)
	{
	struct i2c_esp32_data *data = dev->driver_data;
	int ret = 0;
	u8_t i;

	k_sem_take(&data->transfer_sem, K_FOREVER);

	/* Mask out unused address bits, and make room for R/W bit */
	addr &= BIT_MASK(data->dev_config & I2C_ADDR_10_BITS ? 10 : 7);
	addr <<= 1;

	for (i = 0; i < num_msgs; i++) {
	if ((msgs[i].flags & I2C_MSG_RW_MASK) == I2C_MSG_WRITE) {
	ret = i2c_esp32_write_msg(dev, addr, msgs[i]);
	} else {
	ret = i2c_esp32_read_msg(dev, addr, msgs[i]);
	}

	if (ret < 0) {
	break;
	}
	}

	k_sem_give(&data->transfer_sem);

	return ret;
	}

	static void i2c_esp32_isr(void *arg)
	{
	const int fifo_give_mask = I2C_ACK_ERR_INT_ST \|
	I2C_TIME_OUT_INT_ST \|
	I2C_TRANS_COMPLETE_INT_ST \|
	I2C_ARBITRATION_LOST_INT_ST;
	struct device *device = arg;
	const struct i2c_esp32_config *config = device->config->config_info;

	if (sys_read32(I2C_INT_STATUS_REG(config->index)) & fifo_give_mask) {
	struct i2c_esp32_data *data = device->driver_data;

	/* Only give the semaphore if a watched interrupt happens.
	* Error checking is performed at the other side of the
	* semaphore, by reading the status register.
	*/
	k_sem_give(&data->fifo_sem);
	}

	/* Acknowledge all I2C interrupts */
	sys_write32(~0, I2C_INT_CLR_REG(config->index));
	}

	static int i2c_esp32_init(struct device *dev);

	static const struct i2c_driver_api i2c_esp32_driver_api = {
	.configure = i2c_esp32_configure,
	.transfer = i2c_esp32_transfer,
	};

	#ifdef CONFIG_I2C_0
	DEVICE_DECLARE(i2c_esp32_0);

	static void i2c_esp32_connect_irq_0(void)
	{
	IRQ_CONNECT(CONFIG_I2C_ESP32_0_IRQ, 1, i2c_esp32_isr,
	DEVICE_GET(i2c_esp32_0), 0);
	}

	static const struct i2c_esp32_config i2c_esp32_config_0 = {
	.index = 0,
	.connect_irq = i2c_esp32_connect_irq_0,
	.sig = {
	.sda_out = I2CEXT0_SDA_OUT_IDX,
	.sda_in = I2CEXT0_SDA_IN_IDX,
	.scl_out = I2CEXT0_SCL_OUT_IDX,
	.scl_in = I2CEXT0_SCL_IN_IDX,
	},
	.pins = {
	.scl = CONFIG_I2C_ESP32_0_SCL_PIN,
	.sda = CONFIG_I2C_ESP32_0_SDA_PIN,
	},
	.enable_bits = {
	.clk = DPORT_I2C_EXT0_CLK_EN,
	.rst = DPORT_I2C_EXT0_RST,
	},
	.mode = {
	.tx_lsb_first =
	IS_ENABLED(CONFIG_ESP32_I2C_0_TX_LSB_FIRST),
	.rx_lsb_first =
	IS_ENABLED(CONFIG_ESP32_I2C_0_RX_LSB_FIRST),
	},
	.irq = {
	.source = ETS_I2C_EXT0_INTR_SOURCE,
	.line = CONFIG_I2C_ESP32_0_IRQ,
	},
	.default_config = CONFIG_I2C_0_DEFAULT_CFG,
	};

	static struct i2c_esp32_data i2c_esp32_data_0;

	DEVICE_AND_API_INIT(i2c_esp32_0, CONFIG_I2C_0_NAME, &i2c_esp32_init,
	&i2c_esp32_data_0, &i2c_esp32_config_0,
	POST_KERNEL, CONFIG_I2C_INIT_PRIORITY,
	&i2c_esp32_driver_api);
	#endif /* CONFIG_I2C_0 */

	#ifdef CONFIG_I2C_1
	DEVICE_DECLARE(i2c_esp32_1);

	static void i2c_esp32_connect_irq_1(void)
	{
	IRQ_CONNECT(CONFIG_I2C_ESP32_0_IRQ, 1, i2c_esp32_isr,
	DEVICE_GET(i2c_esp32_1), 0);
	}

	static const struct i2c_esp32_config i2c_esp32_config_1 = {
	.index = 1,
	.connect_irq = i2c_esp32_connect_irq_1,
	.sig = {
	.sda_out = I2CEXT1_SDA_OUT_IDX,
	.sda_in = I2CEXT1_SDA_IN_IDX,
	.scl_out = I2CEXT1_SCL_OUT_IDX,
	.scl_in = I2CEXT1_SCL_IN_IDX,
	},
	.pins = {
	.scl = CONFIG_I2C_ESP32_1_SCL_PIN,
	.sda = CONFIG_I2C_ESP32_1_SDA_PIN,
	},
	.enable_bits = {
	.clk = DPORT_I2C_EXT1_CLK_EN,
	.rst = DPORT_I2C_EXT1_RST,
	},
	.mode = {
	.tx_lsb_first =
	IS_ENABLED(CONFIG_ESP32_I2C_1_TX_LSB_FIRST),
	.rx_lsb_first =
	IS_ENABLED(CONFIG_ESP32_I2C_1_RX_LSB_FIRST),
	},
	.irq = {
	.source = ETS_I2C_EXT1_INTR_SOURCE,
	.line = CONFIG_I2C_ESP32_1_IRQ,
	},
	.default_config = CONFIG_I2C_1_DEFAULT_CFG,
	};

	static struct i2c_esp32_data i2c_esp32_data_1;

	DEVICE_AND_API_INIT(i2c_esp32_1, CONFIG_I2C_1_NAME, &i2c_esp32_init,
	&i2c_esp32_data_1, &i2c_esp32_config_1,
	POST_KERNEL, CONFIG_I2C_INIT_PRIORITY,
	&i2c_esp32_driver_api);
	#endif /* CONFIG_I2C_1 */

	static int i2c_esp32_init(struct device *dev)
	{
	const struct i2c_esp32_config *config = dev->config->config_info;
	struct i2c_esp32_data *data = dev->driver_data;
	int key = irq_lock();

	k_sem_init(&data->fifo_sem, 1, 1);
	k_sem_init(&data->transfer_sem, 1, 1);

	irq_disable(config->irq.line);

	/* Even if irq_enable() is called on config->irq.line, disable
	* interrupt sources in the I2C controller.
	*/
	sys_write32(0, I2C_INT_ENA_REG(config->index));
	esp32_rom_intr_matrix_set(0, config->irq.source, config->irq.line);

	config->connect_irq();
	irq_unlock(key);

	return i2c_esp32_configure(dev, config->default_config);
	}