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pigweed / third_party / github / zephyrproject-rtos / zephyr / a4264f3e86b132d6b708461d8b7732645ecd9148 / . / drivers / i2c / i2c_npcx_controller.c
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/*
* Copyright (c) 2020 Nuvoton Technology Corporation.
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr/pm/policy.h>
#define DT_DRV_COMPAT nuvoton_npcx_i2c_ctrl
/**
* @file
* @brief Nuvoton NPCX smb/i2c module (controller) driver
*
* This file contains the driver of SMB module (controller) which provides full
* support for a two-wire SMBus/I2C synchronous serial interface. The following
* is the state diagrams for each Zephyr i2c api functions.
*
* case 1: i2c_write()/i2c_burst_write()
*
* All msg data sent? Is there next msg?
* +<----------------+<----------------------+
* | No | | Yes
* +------+ +------------+ | +------- ----+ | +------- -------+ |
* +->| IDLE |-->| WAIT_START |--->| WRITE_FIFO |-+--->| WRITE_SUSPEND |--+
* | +------+ +------------+ +------------+ Yes +---------------+ |
* | Issue START START completed | No
* | +-----------+ |
* +--------------------------------------------| WAIT_STOP |<------------+
* STOP is completed +-----------+ Issue STOP
*
*
* case 2: i2c_read()
*
* All msg data received? Is there next msg?
* +<-----------------+<---------------------+
* | No | | Yes
* +------+ +------------+ | +------- ---+ | +------- ------+ |
* +->| IDLE |-->| WAIT_START |--->| READ_FIFO |---+--->| READ_SUSPEND |--+
* | +------+ +------------+ +------------+ Yes +--------------+ |
* | Issue START START completed | No
* | +-----------+ |
* +------------------------------------------| WAIT_STOP |<--------------+
* STOP is completed +-----------+ Issue STOP
*
*
* case 3: i2c_write_read()/i2c_burst_read()
*
* All msg data sent? Is there next write msg?
* +<----------------+<----------------------+
* | No | | Yes
* +------+ +------------+ | +------- ----+ | +------- -------+ |
* +->| IDLE |-->| WAIT_START |--->| WRITE_FIFO |-+--->| WRITE_SUSPEND |--+
* | +------+ +------------+ +------------+ Yes +---------------+ |
* | Issue START START completed | No
* | +---------------------------------------------------------------+
* | |
* | | All msg data received? Is there next read msg?
* | | +<-----------------+<-----------------------+
* | | | No | | Yes
* | | +--------------+ | +------- ---+ | +------- ------+ |
* | +--| WAIT_RESTART |--->| READ_FIFO |---+--->| READ_SUSPEND |----+
* | +--------------+ +-----------+ Yes +--------------+ |
* | Issue RESTART RESTART completed | No
* | +-----------+ |
* +-------------------------------------------| WAIT_STOP |<-------------+
* STOP is completed +-----------+ Issue STOP
*
*/
#include <assert.h>
#include <zephyr/drivers/clock_control.h>
#include <zephyr/drivers/i2c.h>
#include <soc.h>
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(i2c_npcx, LOG_LEVEL_ERR);
/* I2C controller mode */
#define NPCX_I2C_BANK_NORMAL 0
#define NPCX_I2C_BANK_FIFO 1
/* Timeout for device should be available after reset (SMBus spec. unit:ms) */
#define I2C_MAX_TIMEOUT 35
/* Timeout for SCL held to low by slave device . (SMBus spec. unit:ms). */
#define I2C_MIN_TIMEOUT 25
/* Default maximum time we allow for an I2C transfer (unit:ms) */
#define I2C_TRANS_TIMEOUT K_MSEC(100)
/*
* NPCX I2C module that supports FIFO mode has 32 bytes Tx FIFO and
* 32 bytes Rx FIFO.
*/
#define NPCX_I2C_FIFO_MAX_SIZE 32
/* Valid bit fields in SMBST register */
#define NPCX_VALID_SMBST_MASK ~(BIT(NPCX_SMBST_XMIT) | BIT(NPCX_SMBST_MASTER))
/* The delay for the I2C bus recovery bitbang in ~100K Hz */
#define I2C_RECOVER_BUS_DELAY_US 5
#define I2C_RECOVER_SCL_RETRY 10
#define I2C_RECOVER_SDA_RETRY 3
/* Supported I2C bus frequency */
enum npcx_i2c_freq {
NPCX_I2C_BUS_SPEED_100KHZ,
NPCX_I2C_BUS_SPEED_400KHZ,
NPCX_I2C_BUS_SPEED_1MHZ,
};
/*
* Internal SMBus Interface driver states values, which reflect events
* which occurred on the bus
*/
enum npcx_i2c_oper_state {
NPCX_I2C_IDLE,
NPCX_I2C_WAIT_START,
NPCX_I2C_WAIT_RESTART,
NPCX_I2C_WRITE_FIFO,
NPCX_I2C_WRITE_SUSPEND,
NPCX_I2C_READ_FIFO,
NPCX_I2C_READ_SUSPEND,
NPCX_I2C_WAIT_STOP,
NPCX_I2C_ERROR_RECOVERY,
};
/* I2C timing configuration for each i2c speed */
struct npcx_i2c_timing_cfg {
uint8_t HLDT; /* i2c hold-time (Unit: clocks) */
uint8_t k1; /* k1 = SCL low-time (Unit: clocks) */
uint8_t k2; /* k2 = SCL high-time (Unit: clocks) */
};
/* Device config */
struct i2c_ctrl_config {
uintptr_t base; /* i2c controller base address */
struct npcx_clk_cfg clk_cfg; /* clock configuration */
uint8_t irq; /* i2c controller irq */
};
/* Driver data */
struct i2c_ctrl_data {
struct k_sem lock_sem; /* mutex of i2c controller */
struct k_sem sync_sem; /* semaphore used for synchronization */
uint32_t bus_freq; /* operation freq of i2c */
enum npcx_i2c_oper_state oper_state; /* controller operation state */
int trans_err; /* error code during transaction */
struct i2c_msg *msg; /* cache msg for transaction state machine */
int is_write; /* direction of current msg */
uint8_t *ptr_msg; /* current msg pointer for FIFO read/write */
uint16_t addr; /* slave address of transaction */
uint8_t port; /* current port used the controller */
bool is_configured; /* is port configured? */
const struct npcx_i2c_timing_cfg *ptr_speed_confs;
};
/* Driver convenience defines */
#define HAL_I2C_INSTANCE(dev) \
((struct smb_reg *)((const struct i2c_ctrl_config *)(dev)->config)->base)
#define HAL_I2C_FIFO_INSTANCE(dev) \
((struct smb_fifo_reg *)((const struct i2c_ctrl_config *)(dev)->config)->base)
/* Recommended I2C timing values are based on 15 MHz */
static const struct npcx_i2c_timing_cfg npcx_15m_speed_confs[] = {
[NPCX_I2C_BUS_SPEED_100KHZ] = {.HLDT = 15, .k1 = 76, .k2 = 0},
[NPCX_I2C_BUS_SPEED_400KHZ] = {.HLDT = 7, .k1 = 24, .k2 = 18,},
[NPCX_I2C_BUS_SPEED_1MHZ] = {.HLDT = 7, .k1 = 14, .k2 = 10,},
};
static const struct npcx_i2c_timing_cfg npcx_20m_speed_confs[] = {
[NPCX_I2C_BUS_SPEED_100KHZ] = {.HLDT = 15, .k1 = 102, .k2 = 0},
[NPCX_I2C_BUS_SPEED_400KHZ] = {.HLDT = 7, .k1 = 32, .k2 = 22},
[NPCX_I2C_BUS_SPEED_1MHZ] = {.HLDT = 7, .k1 = 16, .k2 = 10},
};
/* I2C controller inline functions access shared registers */
static inline void i2c_ctrl_start(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
inst_fifo->SMBCTL1 |= BIT(NPCX_SMBCTL1_START);
}
static inline void i2c_ctrl_stop(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
inst_fifo->SMBCTL1 |= BIT(NPCX_SMBCTL1_STOP);
}
static inline int i2c_ctrl_bus_busy(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
return IS_BIT_SET(inst_fifo->SMBCST, NPCX_SMBCST_BB);
}
static inline void i2c_ctrl_bank_sel(const struct device *dev, int bank)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
if (bank) {
inst->SMBCTL3 |= BIT(NPCX_SMBCTL3_BNK_SEL);
} else {
inst->SMBCTL3 &= ~BIT(NPCX_SMBCTL3_BNK_SEL);
}
}
static inline void i2c_ctrl_irq_enable(const struct device *dev, int enable)
{
const struct i2c_ctrl_config *const config = dev->config;
if (enable) {
irq_enable(config->irq);
} else {
irq_disable(config->irq);
}
}
/* I2C controller inline functions access registers in 'Normal' bank */
static inline void i2c_ctrl_norm_stall_scl(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
/* Enable writing to SCL_LVL/SDA_LVL bit in SMBnCTL3 */
inst->SMBCTL4 |= BIT(NPCX_SMBCTL4_LVL_WE);
/* Force SCL bus to low and keep SDA floating */
inst->SMBCTL3 = (inst->SMBCTL3 & ~BIT(NPCX_SMBCTL3_SCL_LVL))
| BIT(NPCX_SMBCTL3_SDA_LVL);
/* Disable writing to them */
inst->SMBCTL4 &= ~BIT(NPCX_SMBCTL4_LVL_WE);
}
static inline void i2c_ctrl_norm_free_scl(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
/* Enable writing to SCL_LVL/SDA_LVL bit in SMBnCTL3 */
inst->SMBCTL4 |= BIT(NPCX_SMBCTL4_LVL_WE);
/*
* Release SCL bus. Then it might be still driven by module itself or
* slave device.
*/
inst->SMBCTL3 |= BIT(NPCX_SMBCTL3_SCL_LVL) | BIT(NPCX_SMBCTL3_SDA_LVL);
/* Disable writing to them */
inst->SMBCTL4 &= ~BIT(NPCX_SMBCTL4_LVL_WE);
}
/* I2C controller inline functions access registers in 'Normal' bank */
static inline void i2c_ctrl_norm_stall_sda(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
/* Enable writing to SCL_LVL/SDA_LVL bit in SMBnCTL3 */
inst->SMBCTL4 |= BIT(NPCX_SMBCTL4_LVL_WE);
/* Force SDA bus to low and keep SCL floating */
inst->SMBCTL3 = (inst->SMBCTL3 & ~BIT(NPCX_SMBCTL3_SDA_LVL))
| BIT(NPCX_SMBCTL3_SCL_LVL);
/* Disable writing to them */
inst->SMBCTL4 &= ~BIT(NPCX_SMBCTL4_LVL_WE);
}
static inline void i2c_ctrl_norm_free_sda(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
/* Enable writing to SCL_LVL/SDA_LVL bit in SMBnCTL3 */
inst->SMBCTL4 |= BIT(NPCX_SMBCTL4_LVL_WE);
/*
* Release SDA bus. Then it might be still driven by module itself or
* slave device.
*/
inst->SMBCTL3 |= BIT(NPCX_SMBCTL3_SDA_LVL) | BIT(NPCX_SMBCTL3_SCL_LVL);
/* Disable writing to them */
inst->SMBCTL4 &= ~BIT(NPCX_SMBCTL4_LVL_WE);
}
/* I2C controller inline functions access registers in 'FIFO' bank */
static inline void i2c_ctrl_fifo_write(const struct device *dev, uint8_t data)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
inst_fifo->SMBSDA = data;
}
static inline uint8_t i2c_ctrl_fifo_read(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
return inst_fifo->SMBSDA;
}
static inline int i2c_ctrl_fifo_tx_avail(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
return NPCX_I2C_FIFO_MAX_SIZE - (inst_fifo->SMBTXF_STS & 0x3f);
}
static inline int i2c_ctrl_fifo_rx_occupied(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
return inst_fifo->SMBRXF_STS & 0x3f;
}
static inline void i2c_ctrl_fifo_rx_setup_threshold_nack(
const struct device *dev, int threshold, int last)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
uint8_t value = MIN(threshold, NPCX_I2C_FIFO_MAX_SIZE);
SET_FIELD(inst_fifo->SMBRXF_CTL, NPCX_SMBRXF_CTL_RX_THR, value);
/*
* Is it last received transaction? If so, set LAST bit. Then the
* hardware will generate NACK automatically when receiving last byte.
*/
if (last && (value == threshold)) {
inst_fifo->SMBRXF_CTL |= BIT(NPCX_SMBRXF_CTL_LAST);
}
}
static inline void i2c_ctrl_fifo_clear_status(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
inst_fifo->SMBFIF_CTS |= BIT(NPCX_SMBFIF_CTS_CLR_FIFO);
}
/*
* I2C local functions which touch the registers in 'Normal' bank. These
* utilities will change bank back to FIFO mode when leaving themselves in case
* the other utilities access the registers in 'FIFO' bank.
*/
static void i2c_ctrl_hold_bus(const struct device *dev, int stall)
{
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_NORMAL);
if (stall) {
i2c_ctrl_norm_stall_scl(dev);
} else {
i2c_ctrl_norm_free_scl(dev);
}
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_FIFO);
}
static void i2c_ctrl_init_module(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_NORMAL);
/* Enable FIFO mode first */
inst->SMBFIF_CTL |= BIT(NPCX_SMBFIF_CTL_FIFO_EN);
/* Enable module - before configuring CTL1 */
inst->SMBCTL2 |= BIT(NPCX_SMBCTL2_ENABLE);
/* Enable SMB interrupt and 'New Address Match' interrupt source */
inst->SMBCTL1 |= BIT(NPCX_SMBCTL1_NMINTE) | BIT(NPCX_SMBCTL1_INTEN);
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_FIFO);
}
static void i2c_ctrl_config_bus_freq(const struct device *dev,
enum npcx_i2c_freq bus_freq)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
struct i2c_ctrl_data *const data = dev->data;
const struct npcx_i2c_timing_cfg bus_cfg =
data->ptr_speed_confs[bus_freq];
/* Switch to bank 0 to configure bus speed */
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_NORMAL);
/* Configure bus speed */
if (bus_freq == NPCX_I2C_BUS_SPEED_100KHZ) {
/* Enable 'Normal' Mode */
inst->SMBCTL3 &= ~(BIT(NPCX_SMBCTL3_400K));
/* Set freq of SCL. For 100KHz, only k1 is used. */
SET_FIELD(inst->SMBCTL2, NPCX_SMBCTL2_SCLFRQ0_6_FIELD,
bus_cfg.k1/2 & 0x7f);
SET_FIELD(inst->SMBCTL3, NPCX_SMBCTL3_SCLFRQ7_8_FIELD,
bus_cfg.k1/2 >> 7);
SET_FIELD(inst->SMBCTL4, NPCX_SMBCTL4_HLDT_FIELD,
bus_cfg.HLDT);
} else {
/* Enable 'Fast' Mode for 400K or higher freq. */
inst->SMBCTL3 |= BIT(NPCX_SMBCTL3_400K);
/* Set high/low time of SCL and hold-time */
inst->SMBSCLLT = bus_cfg.k1/2;
inst->SMBSCLHT = bus_cfg.k2/2;
SET_FIELD(inst->SMBCTL4, NPCX_SMBCTL4_HLDT_FIELD,
bus_cfg.HLDT);
}
/* Switch to bank 1 to access I2C FIFO registers */
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_FIFO);
}
/* I2C controller local functions */
static int i2c_ctrl_wait_stop_completed(const struct device *dev, int timeout)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
if (timeout <= 0) {
return -EINVAL;
}
do {
/*
* Wait till i2c bus is idle. This bit is cleared to 0
* automatically after the STOP condition is generated.
*/
if (!IS_BIT_SET(inst_fifo->SMBCTL1, NPCX_SMBCTL1_STOP))
break;
k_msleep(1);
} while (--timeout);
if (timeout > 0) {
return 0;
} else {
return -ETIMEDOUT;
}
}
static bool i2c_ctrl_is_scl_sda_both_high(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
if (IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SCL_LVL) &&
IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SDA_LVL)) {
return true;
}
return false;
}
static int i2c_ctrl_wait_idle_completed(const struct device *dev, int timeout)
{
if (timeout <= 0) {
return -EINVAL;
}
do {
/* Wait for both SCL & SDA lines are high */
if (i2c_ctrl_is_scl_sda_both_high(dev)) {
break;
}
k_msleep(1);
} while (--timeout);
if (timeout > 0) {
return 0;
} else {
return -ETIMEDOUT;
}
}
static int i2c_ctrl_recovery(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
struct i2c_ctrl_data *const data = dev->data;
int ret;
if (data->oper_state != NPCX_I2C_ERROR_RECOVERY) {
data->oper_state = NPCX_I2C_ERROR_RECOVERY;
}
/* Step 1: Make sure the bus is not stalled before exit. */
i2c_ctrl_hold_bus(dev, 0);
/*
* Step 2: Abort data, wait for STOP condition completed.
* - Clearing NEGACK and BER bits first
* - Wait for STOP condition completed
* - Then clear BB (BUS BUSY) bit
*/
inst_fifo->SMBST = BIT(NPCX_SMBST_BER) | BIT(NPCX_SMBST_NEGACK);
ret = i2c_ctrl_wait_stop_completed(dev, I2C_MAX_TIMEOUT);
inst_fifo->SMBCST |= BIT(NPCX_SMBCST_BB);
if (ret != 0) {
LOG_ERR("Abort i2c port%02x fail! Bus might be stalled.",
data->port);
}
/*
* Step 3: Reset i2c module to clear all internal state machine of it
* - Disable the SMB module first
* - Wait both SCL/SDA line are high
* - Enable i2c module again
*/
inst_fifo->SMBCTL2 &= ~BIT(NPCX_SMBCTL2_ENABLE);
ret = i2c_ctrl_wait_idle_completed(dev, I2C_MAX_TIMEOUT);
if (ret != 0) {
LOG_ERR("Reset i2c port%02x fail! Bus might be stalled.",
data->port);
return -EIO;
}
/* Reset module and internal state machine */
i2c_ctrl_init_module(dev);
/* Recovery is completed */
data->oper_state = NPCX_I2C_IDLE;
return 0;
}
static void i2c_ctrl_notify(const struct device *dev, int error)
{
struct i2c_ctrl_data *const data = dev->data;
data->trans_err = error;
k_sem_give(&data->sync_sem);
}
static int i2c_ctrl_wait_completion(const struct device *dev)
{
struct i2c_ctrl_data *const data = dev->data;
if (k_sem_take(&data->sync_sem, I2C_TRANS_TIMEOUT) == 0) {
return data->trans_err;
} else {
return -ETIMEDOUT;
}
}
size_t i2c_ctrl_calculate_msg_remains(const struct device *dev)
{
struct i2c_ctrl_data *const data = dev->data;
uint8_t *buf_end = data->msg->buf + data->msg->len;
return (buf_end > data->ptr_msg) ? (buf_end - data->ptr_msg) : 0;
}
static void i2c_ctrl_handle_write_int_event(const struct device *dev)
{
struct i2c_ctrl_data *const data = dev->data;
/* START condition is issued */
if (data->oper_state == NPCX_I2C_WAIT_START) {
/* Write slave address with W bit */
i2c_ctrl_fifo_write(dev, ((data->addr << 1) & ~BIT(0)));
/* Start to proceed write process */
data->oper_state = NPCX_I2C_WRITE_FIFO;
return;
}
/* Write message data bytes to FIFO */
if (data->oper_state == NPCX_I2C_WRITE_FIFO) {
/* Calculate how many remaining bytes need to transmit */
size_t tx_remain = i2c_ctrl_calculate_msg_remains(dev);
size_t tx_avail = MIN(tx_remain, i2c_ctrl_fifo_tx_avail(dev));
LOG_DBG("tx remains %d, avail %d", tx_remain, tx_avail);
for (int i = 0U; i < tx_avail; i++) {
i2c_ctrl_fifo_write(dev, *(data->ptr_msg++));
}
/* Is there any remaining bytes? */
if (data->ptr_msg == data->msg->buf + data->msg->len) {
data->oper_state = NPCX_I2C_WRITE_SUSPEND;
}
return;
}
/* Issue STOP after sending message? */
if (data->oper_state == NPCX_I2C_WRITE_SUSPEND) {
if (data->msg->flags & I2C_MSG_STOP) {
/* Generate a STOP condition immediately */
i2c_ctrl_stop(dev);
/* Clear rx FIFO threshold and status bits */
i2c_ctrl_fifo_clear_status(dev);
/* Wait for STOP completed */
data->oper_state = NPCX_I2C_WAIT_STOP;
} else {
/* Disable interrupt and handle next message */
i2c_ctrl_irq_enable(dev, 0);
}
}
return i2c_ctrl_notify(dev, 0);
}
static void i2c_ctrl_handle_read_int_event(const struct device *dev)
{
struct i2c_ctrl_data *const data = dev->data;
/* START or RESTART condition is issued */
if (data->oper_state == NPCX_I2C_WAIT_START ||
data->oper_state == NPCX_I2C_WAIT_RESTART) {
/* Setup threshold of rx FIFO before sending address byte */
i2c_ctrl_fifo_rx_setup_threshold_nack(dev, data->msg->len,
(data->msg->flags & I2C_MSG_STOP) != 0);
/* Write slave address with R bit */
i2c_ctrl_fifo_write(dev, ((data->addr << 1) | BIT(0)));
/* Start to proceed read process */
data->oper_state = NPCX_I2C_READ_FIFO;
return;
}
/* Read message data bytes from FIFO */
if (data->oper_state == NPCX_I2C_READ_FIFO) {
/* Calculate how many remaining bytes need to receive */
size_t rx_remain = i2c_ctrl_calculate_msg_remains(dev);
size_t rx_occupied = i2c_ctrl_fifo_rx_occupied(dev);
LOG_DBG("rx remains %d, occupied %d", rx_remain, rx_occupied);
/* Is it the last read transaction with STOP condition? */
if (rx_occupied >= rx_remain &&
(data->msg->flags & I2C_MSG_STOP) != 0) {
/*
* Generate a STOP condition before reading data bytes
* from FIFO. It prevents a glitch on SCL.
*/
i2c_ctrl_stop(dev);
} else {
/*
* Hold SCL line here in case the hardware releases bus
* immediately after the driver start to read data from
* FIFO. Then we might lose incoming data from device.
*/
i2c_ctrl_hold_bus(dev, 1);
}
/* Read data bytes from FIFO */
for (int i = 0; i < rx_occupied; i++) {
*(data->ptr_msg++) = i2c_ctrl_fifo_read(dev);
}
rx_remain = i2c_ctrl_calculate_msg_remains(dev);
/* Setup threshold of RX FIFO if needed */
if (rx_remain > 0) {
i2c_ctrl_fifo_rx_setup_threshold_nack(dev, rx_remain,
(data->msg->flags & I2C_MSG_STOP) != 0);
/* Release bus */
i2c_ctrl_hold_bus(dev, 0);
return;
}
}
/* Is the STOP condition issued? */
if ((data->msg->flags & I2C_MSG_STOP) != 0) {
/* Clear rx FIFO threshold and status bits */
i2c_ctrl_fifo_clear_status(dev);
/* Wait for STOP completed */
data->oper_state = NPCX_I2C_WAIT_STOP;
} else {
/* Disable i2c interrupt first */
i2c_ctrl_irq_enable(dev, 0);
data->oper_state = NPCX_I2C_READ_SUSPEND;
}
return i2c_ctrl_notify(dev, 0);
}
static int i2c_ctrl_proc_write_msg(const struct device *dev,
struct i2c_msg *msg)
{
struct i2c_ctrl_data *const data = dev->data;
data->is_write = 1;
data->ptr_msg = msg->buf;
data->msg = msg;
if (data->oper_state == NPCX_I2C_IDLE) {
data->oper_state = NPCX_I2C_WAIT_START;
/* Clear FIFO status before starting a new transaction */
i2c_ctrl_fifo_clear_status(dev);
/* Issue a START, wait for transaction completed */
i2c_ctrl_start(dev);
return i2c_ctrl_wait_completion(dev);
} else if (data->oper_state == NPCX_I2C_WRITE_SUSPEND) {
data->oper_state = NPCX_I2C_WRITE_FIFO;
i2c_ctrl_irq_enable(dev, 1);
return i2c_ctrl_wait_completion(dev);
}
LOG_ERR("Unexpected state %d during writing i2c port%02x!",
data->oper_state, data->port);
data->trans_err = -EIO;
return data->trans_err;
}
static int i2c_ctrl_proc_read_msg(const struct device *dev, struct i2c_msg *msg)
{
struct i2c_ctrl_data *const data = dev->data;
data->is_write = 0;
data->ptr_msg = msg->buf;
data->msg = msg;
if (data->oper_state == NPCX_I2C_IDLE) {
data->oper_state = NPCX_I2C_WAIT_START;
/* Clear FIFO status before starting a new transaction */
i2c_ctrl_fifo_clear_status(dev);
/* Issue a START, wait for transaction completed */
i2c_ctrl_start(dev);
return i2c_ctrl_wait_completion(dev);
} else if (data->oper_state == NPCX_I2C_WRITE_SUSPEND) {
data->oper_state = NPCX_I2C_WAIT_RESTART;
/* Issue a RESTART, wait for transaction completed */
i2c_ctrl_start(dev);
i2c_ctrl_irq_enable(dev, 1);
return i2c_ctrl_wait_completion(dev);
} else if (data->oper_state == NPCX_I2C_READ_SUSPEND) {
data->oper_state = NPCX_I2C_READ_FIFO;
/* Setup threshold of RX FIFO first */
i2c_ctrl_fifo_rx_setup_threshold_nack(dev, msg->len,
(msg->flags & I2C_MSG_STOP) != 0);
/* Release bus */
i2c_ctrl_hold_bus(dev, 0);
/* Enable i2c interrupt first */
i2c_ctrl_irq_enable(dev, 1);
return i2c_ctrl_wait_completion(dev);
}
LOG_ERR("Unexpected state %d during reading i2c port%02x!",
data->oper_state, data->port);
data->trans_err = -EIO;
return data->trans_err;
}
/* I2C controller isr function */
static void i2c_ctrl_isr(const struct device *dev)
{
struct smb_fifo_reg *const inst_fifo = HAL_I2C_FIFO_INSTANCE(dev);
struct i2c_ctrl_data *const data = dev->data;
uint8_t status, tmp;
status = inst_fifo->SMBST & NPCX_VALID_SMBST_MASK;
LOG_DBG("status: %02x, %d", status, data->oper_state);
/* A 'Bus Error' has been identified */
if (IS_BIT_SET(status, NPCX_SMBST_BER)) {
/* Generate a STOP condition immediately */
i2c_ctrl_stop(dev);
/* Clear BER Bit */
inst_fifo->SMBST = BIT(NPCX_SMBST_BER);
/* Make sure slave doesn't hold bus by reading FIFO again */
tmp = i2c_ctrl_fifo_read(dev);
LOG_ERR("Bus error occurred on i2c port%02x!", data->port);
data->oper_state = NPCX_I2C_ERROR_RECOVERY;
/* I/O error occurred */
i2c_ctrl_notify(dev, -EIO);
return;
}
/* A negative acknowledge has occurred */
if (IS_BIT_SET(status, NPCX_SMBST_NEGACK)) {
/* Generate a STOP condition immediately */
i2c_ctrl_stop(dev);
/* Clear NEGACK Bit */
inst_fifo->SMBST = BIT(NPCX_SMBST_NEGACK);
/* End transaction */
data->oper_state = NPCX_I2C_WAIT_STOP;
/* No such device or address */
return i2c_ctrl_notify(dev, -ENXIO);
}
/* START, tx FIFO empty or rx FIFO full has occurred */
if (IS_BIT_SET(status, NPCX_SMBST_SDAST)) {
if (data->is_write) {
return i2c_ctrl_handle_write_int_event(dev);
} else {
return i2c_ctrl_handle_read_int_event(dev);
}
}
/* Clear unexpected status bits */
if (status != 0) {
inst_fifo->SMBST = status;
LOG_ERR("Unexpected SMBST 0x%02x occurred on i2c port%02x!",
status, data->port);
}
}
/* NPCX specific I2C controller functions */
void npcx_i2c_ctrl_mutex_lock(const struct device *i2c_dev)
{
struct i2c_ctrl_data *const data = i2c_dev->data;
k_sem_take(&data->lock_sem, K_FOREVER);
}
void npcx_i2c_ctrl_mutex_unlock(const struct device *i2c_dev)
{
struct i2c_ctrl_data *const data = i2c_dev->data;
k_sem_give(&data->lock_sem);
}
int npcx_i2c_ctrl_configure(const struct device *i2c_dev, uint32_t dev_config)
{
struct i2c_ctrl_data *const data = i2c_dev->data;
switch (I2C_SPEED_GET(dev_config)) {
case I2C_SPEED_STANDARD:
data->bus_freq = NPCX_I2C_BUS_SPEED_100KHZ;
break;
case I2C_SPEED_FAST:
data->bus_freq = NPCX_I2C_BUS_SPEED_400KHZ;
break;
case I2C_SPEED_FAST_PLUS:
data->bus_freq = NPCX_I2C_BUS_SPEED_1MHZ;
break;
default:
return -ERANGE;
}
i2c_ctrl_config_bus_freq(i2c_dev, data->bus_freq);
data->is_configured = true;
return 0;
}
int npcx_i2c_ctrl_get_speed(const struct device *i2c_dev, uint32_t *speed)
{
struct i2c_ctrl_data *const data = i2c_dev->data;
if (!data->is_configured) {
return -EIO;
}
switch (data->bus_freq) {
case NPCX_I2C_BUS_SPEED_100KHZ:
*speed = I2C_SPEED_SET(I2C_SPEED_STANDARD);
break;
case NPCX_I2C_BUS_SPEED_400KHZ:
*speed = I2C_SPEED_SET(I2C_SPEED_FAST);
break;
case NPCX_I2C_BUS_SPEED_1MHZ:
*speed = I2C_SPEED_SET(I2C_SPEED_FAST_PLUS);
break;
default:
return -ERANGE;
}
return 0;
}
int npcx_i2c_ctrl_recover_bus(const struct device *dev)
{
struct smb_reg *const inst = HAL_I2C_INSTANCE(dev);
int ret = 0;
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_NORMAL);
/*
* When the SCL is low, wait for a while in case of the clock is stalled
* by a I2C target.
*/
if (!IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SCL_LVL)) {
for (int i = 0;; i++) {
if (i >= I2C_RECOVER_SCL_RETRY) {
ret = -EBUSY;
goto recover_exit;
}
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
if (IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SCL_LVL)) {
break;
}
}
}
if (IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SDA_LVL)) {
goto recover_exit;
}
for (int i = 0; i < I2C_RECOVER_SDA_RETRY; i++) {
/* Drive the clock high. */
i2c_ctrl_norm_free_scl(dev);
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
/*
* Toggle SCL to generate 9 clocks. If the I2C target releases the SDA, we can stop
* toggle the SCL and issue a STOP.
*/
for (int j = 0; j < 9; j++) {
if (IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SDA_LVL)) {
break;
}
i2c_ctrl_norm_stall_scl(dev);
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
i2c_ctrl_norm_free_scl(dev);
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
}
/* Drive the SDA line to issue STOP. */
i2c_ctrl_norm_stall_sda(dev);
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
i2c_ctrl_norm_free_sda(dev);
k_busy_wait(I2C_RECOVER_BUS_DELAY_US);
if (i2c_ctrl_is_scl_sda_both_high(dev)) {
ret = 0;
goto recover_exit;
}
}
if (!IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SDA_LVL)) {
LOG_ERR("Recover SDA fail");
ret = -EBUSY;
}
if (!IS_BIT_SET(inst->SMBCTL3, NPCX_SMBCTL3_SCL_LVL)) {
LOG_ERR("Recover SCL fail");
ret = -EBUSY;
}
recover_exit:
i2c_ctrl_bank_sel(dev, NPCX_I2C_BANK_FIFO);
return ret;
}
int npcx_i2c_ctrl_transfer(const struct device *i2c_dev, struct i2c_msg *msgs,
uint8_t num_msgs, uint16_t addr, int port)
{
struct i2c_ctrl_data *const data = i2c_dev->data;
int ret = 0;
uint8_t i;
/*
* suspend-to-idle stops SMB module clocks (derived from APB2/APB3), which must remain
* active during a transaction
*/
pm_policy_state_lock_get(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES);
/* Does bus need recovery? */
if (data->oper_state != NPCX_I2C_WRITE_SUSPEND &&
data->oper_state != NPCX_I2C_READ_SUSPEND) {
if (i2c_ctrl_bus_busy(i2c_dev) || !i2c_ctrl_is_scl_sda_both_high(i2c_dev) ||
data->oper_state == NPCX_I2C_ERROR_RECOVERY) {
ret = npcx_i2c_ctrl_recover_bus(i2c_dev);
if (ret != 0) {
LOG_ERR("Recover Bus failed");
goto out;
}
ret = i2c_ctrl_recovery(i2c_dev);
/* Recovery failed, return it immediately */
if (ret) {
goto out;
}
}
}
/* Start i2c transaction */
data->port = port;
data->trans_err = 0;
data->addr = addr;
/*
* Reset i2c event-completed semaphore before starting transactions.
* Some interrupt events such as BUS_ERROR might change its counter
* when bus is idle.
*/
k_sem_reset(&data->sync_sem);
for (i = 0U; i < num_msgs; i++) {
struct i2c_msg *msg = msgs + i;
/* Handle write transaction */
if ((msg->flags & I2C_MSG_RW_MASK) == I2C_MSG_WRITE) {
ret = i2c_ctrl_proc_write_msg(i2c_dev, msg);
} else {/* Handle read transaction */
ret = i2c_ctrl_proc_read_msg(i2c_dev, msg);
}
if (ret < 0) {
break;
}
}
/* Check STOP completed? */
if (data->oper_state == NPCX_I2C_WAIT_STOP) {
data->trans_err = i2c_ctrl_wait_stop_completed(i2c_dev,
I2C_MIN_TIMEOUT);
if (data->trans_err == 0) {
data->oper_state = NPCX_I2C_IDLE;
} else {
LOG_ERR("STOP fail! bus is held on i2c port%02x!",
data->port);
data->oper_state = NPCX_I2C_ERROR_RECOVERY;
}
}
if (data->oper_state == NPCX_I2C_ERROR_RECOVERY) {
int recovery_error = i2c_ctrl_recovery(i2c_dev);
/*
* Recovery failed, return it immediately. Otherwise, the upper
* layer still needs to know why the transaction failed.
*/
if (recovery_error != 0) {
ret = recovery_error;
}
}
out:
pm_policy_state_lock_put(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES);
return ret;
}
/* I2C controller driver registration */
static int i2c_ctrl_init(const struct device *dev)
{
const struct i2c_ctrl_config *const config = dev->config;
struct i2c_ctrl_data *const data = dev->data;
const struct device *const clk_dev = DEVICE_DT_GET(NPCX_CLK_CTRL_NODE);
uint32_t i2c_rate;
if (!device_is_ready(clk_dev)) {
LOG_ERR("clock control device not ready");
return -ENODEV;
}
/* Turn on device clock first and get source clock freq. */
if (clock_control_on(clk_dev,
(clock_control_subsys_t *) &config->clk_cfg) != 0) {
LOG_ERR("Turn on %s clock fail.", dev->name);
return -EIO;
}
/*
* If apb2/3's clock is not 15MHz, we need to add the other timing
* configuration of the device to meet SMBus timing spec. Please refer
* Table 21/22/23 and section 7.5.9 SMBus Timing for more detail.
*/
if (clock_control_get_rate(clk_dev, (clock_control_subsys_t *)
&config->clk_cfg, &i2c_rate) != 0) {
LOG_ERR("Get %s clock rate error.", dev->name);
return -EIO;
}
if (i2c_rate == 15000000) {
data->ptr_speed_confs = npcx_15m_speed_confs;
} else if (i2c_rate == 20000000) {
data->ptr_speed_confs = npcx_20m_speed_confs;
} else {
LOG_ERR("Unsupported apb2/3 freq for %s.", dev->name);
return -EIO;
}
/* Initialize i2c module */
i2c_ctrl_init_module(dev);
/* initialize mutex and semaphore for i2c/smb controller */
k_sem_init(&data->lock_sem, 1, 1);
k_sem_init(&data->sync_sem, 0, K_SEM_MAX_LIMIT);
/* Initialize driver status machine */
data->oper_state = NPCX_I2C_IDLE;
return 0;
}
/* I2C controller init macro functions */
#define NPCX_I2C_CTRL_INIT_FUNC(inst) _CONCAT(i2c_ctrl_init_, inst)
#define NPCX_I2C_CTRL_INIT_FUNC_DECL(inst) \
static int i2c_ctrl_init_##inst(const struct device *dev)
#define NPCX_I2C_CTRL_INIT_FUNC_IMPL(inst) \
static int i2c_ctrl_init_##inst(const struct device *dev) \
{ \
int ret; \
\
ret = i2c_ctrl_init(dev); \
IRQ_CONNECT(DT_INST_IRQN(inst), \
DT_INST_IRQ(inst, priority), \
i2c_ctrl_isr, \
DEVICE_DT_INST_GET(inst), \
0); \
irq_enable(DT_INST_IRQN(inst)); \
\
return ret; \
}
#define NPCX_I2C_CTRL_INIT(inst) \
NPCX_I2C_CTRL_INIT_FUNC_DECL(inst); \
\
static const struct i2c_ctrl_config i2c_ctrl_cfg_##inst = { \
.base = DT_INST_REG_ADDR(inst), \
.irq = DT_INST_IRQN(inst), \
.clk_cfg = NPCX_DT_CLK_CFG_ITEM(inst), \
}; \
\
static struct i2c_ctrl_data i2c_ctrl_data_##inst; \
\
I2C_DEVICE_DT_INST_DEFINE(inst, \
NPCX_I2C_CTRL_INIT_FUNC(inst), \
NULL, \
&i2c_ctrl_data_##inst, &i2c_ctrl_cfg_##inst, \
PRE_KERNEL_1, CONFIG_I2C_INIT_PRIORITY, \
NULL); \
\
NPCX_I2C_CTRL_INIT_FUNC_IMPL(inst)
DT_INST_FOREACH_STATUS_OKAY(NPCX_I2C_CTRL_INIT)