i2c.c
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/*
* Copyright (C) 2014 FU Berlin
*
* This file is subject to the terms and conditions of the GNU Lesser
* General Public License v2.1. See the file LICENSE in the top level
* directory for more details.
*/
/**
* @ingroup cpu_stm32f2
* @ingroup drivers_periph_i2c
* @{
*
* @file
* @brief Low-level I2C driver implementation
*
* @note This implementation only implements the 7-bit addressing mode.
*
* @author Toon Stegen <toon.stegen@altran.com>
* @author Vincent Dupont <vincent@otakeys.com>
*
* @}
*/
#include <stdint.h>
#include "cpu.h"
#include "irq.h"
#include "mutex.h"
#include "periph_conf.h"
#include "periph/i2c.h"
#define ENABLE_DEBUG (0)
#include "debug.h"
/* guard file in case no I2C device is defined */
#if I2C_NUMOF
#define I2C_MAX_LOOP_CNT 10000
/* static function definitions */
static int _read_bytes(I2C_TypeDef *i2c, uint8_t address, uint8_t *data, int length, uint8_t *err);
static void _i2c_init(I2C_TypeDef *i2c, int ccr);
static void _pin_config(GPIO_TypeDef *port_scl, GPIO_TypeDef *port_sda, int pin_scl, int pin_sda);
static int _start(I2C_TypeDef *dev, uint8_t address, uint8_t rw_flag, uint8_t *err);
static inline void _clear_addr(I2C_TypeDef *dev);
static inline int _write(I2C_TypeDef *dev, const uint8_t *data, int length, uint8_t *err);
static inline int _stop(I2C_TypeDef *dev, uint8_t *err);
static inline int _wait_ready(I2C_TypeDef *dev);
/**
* @brief Array holding one pre-initialized mutex for each I2C device
*/
static mutex_t locks[] = {
#if I2C_0_EN
[I2C_0] = MUTEX_INIT,
#endif
#if I2C_1_EN
[I2C_1] = MUTEX_INIT,
#endif
#if I2C_2_EN
[I2C_2] = MUTEX_INIT,
#endif
#if I2C_3_EN
[I2C_3] = MUTEX_INIT
#endif
};
static uint8_t err_flag[] = {
#if I2C_0_EN
[I2C_0] = 0x00,
#endif
#if I2C_1_EN
[I2C_1] = 0x00,
#endif
#if I2C_2_EN
[I2C_2] = 0x00,
#endif
#if I2C_3_EN
[I2C_3] = 0x00
#endif
};
int i2c_init_master(i2c_t dev, i2c_speed_t speed)
{
I2C_TypeDef *i2c;
GPIO_TypeDef *port_scl;
GPIO_TypeDef *port_sda;
int pin_scl = 0, pin_sda = 0;
int ccr;
/* read speed configuration */
switch (speed) {
case I2C_SPEED_NORMAL:
ccr = I2C_APBCLK / 200000;
break;
case I2C_SPEED_FAST:
ccr = I2C_APBCLK / 800000;
break;
default:
return -2;
}
/* read static device configuration */
switch (dev) {
#if I2C_0_EN
case I2C_0:
i2c = I2C_0_DEV;
port_scl = I2C_0_SCL_PORT;
pin_scl = I2C_0_SCL_PIN;
port_sda = I2C_0_SDA_PORT;
pin_sda = I2C_0_SDA_PIN;
I2C_0_CLKEN();
I2C_0_SCL_CLKEN();
I2C_0_SDA_CLKEN();
NVIC_SetPriority(I2C_0_ERR_IRQ, I2C_IRQ_PRIO);
NVIC_EnableIRQ(I2C_0_ERR_IRQ);
break;
#endif
default:
return -1;
}
/* configure pins */
_pin_config(port_scl, port_sda, pin_scl, pin_sda);
/* configure device */
_i2c_init(i2c, ccr);
return 0;
}
static void _i2c_init(I2C_TypeDef *i2c, int ccr)
{
/* disable device and set ACK bit */
i2c->CR1 = I2C_CR1_ACK;
/* configure I2C clock */
i2c->CR2 = (I2C_APBCLK / 1000000) | I2C_CR2_ITERREN;
i2c->CCR = ccr;
i2c->TRISE = (I2C_APBCLK / 1000000) + 1;
/* configure device */
i2c->OAR1 |= (1 << 14); /* datasheet: bit 14 should be kept 1 */
i2c->OAR1 &= ~I2C_OAR1_ADDMODE; /* make sure we are in 7-bit address mode */
/* enable device */
i2c->CR1 |= I2C_CR1_PE;
}
static void _pin_config(GPIO_TypeDef *port_scl, GPIO_TypeDef *port_sda, int pin_scl, int pin_sda)
{
/* Set GPIOs to AF mode */
port_scl->MODER &= ~(3 << (2 * pin_scl));
port_scl->MODER |= (2 << (2 * pin_scl));
port_sda->MODER &= ~(3 << (2 * pin_sda));
port_sda->MODER |= (2 << (2 * pin_sda));
/* Set speed high*/
port_scl->OSPEEDR |= (3 << (2 * pin_scl));
port_sda->OSPEEDR |= (3 << (2 * pin_sda));
/* Set to push-pull configuration open drain*/
port_scl->OTYPER |= (1 << pin_scl);
port_sda->OTYPER |= (1 << pin_sda);
/* Enable pull-up resistors */
port_scl->PUPDR &= ~(3 << (2 * pin_scl));
port_sda->PUPDR &= ~(3 << (2 * pin_sda));
if (I2C_0_SCL_PULLUP) {
port_scl->PUPDR |= (1 << (2 * pin_scl));
}
if (I2C_0_SDA_PULLUP) {
port_sda->PUPDR |= (1 << (2 * pin_sda));
}
/* Configure GPIOs to for the I2C alternate function */
if (pin_scl < 8) {
port_scl->AFR[0] &= ~(0xf << (4 * pin_scl));
port_scl->AFR[0] |= (I2C_0_SCL_AF << (4 * pin_scl));
}
else {
port_scl->AFR[1] &= ~(0xf << (4 * (pin_scl - 8)));
port_scl->AFR[1] |= (I2C_0_SCL_AF << (4 * (pin_scl - 8)));
}
if (pin_sda < 8) {
port_sda->AFR[0] &= ~(0xf << (4 * pin_sda));
port_sda->AFR[0] |= (I2C_0_SDA_AF << (4 * pin_sda));
}
else {
port_sda->AFR[1] &= ~(0xf << (4 * (pin_sda - 8)));
port_sda->AFR[1] |= (I2C_0_SDA_AF << (4 * (pin_sda - 8)));
}
}
int i2c_acquire(i2c_t dev)
{
if (dev >= I2C_NUMOF) {
return -1;
}
mutex_lock(&locks[dev]);
return 0;
}
int i2c_release(i2c_t dev)
{
if (dev >= I2C_NUMOF) {
return -1;
}
mutex_unlock(&locks[dev]);
return 0;
}
int i2c_read_byte(i2c_t dev, uint8_t address, void *data)
{
return i2c_read_bytes(dev, address, data, 1);
}
int i2c_read_bytes(i2c_t dev, uint8_t address, void *data, int length)
{
I2C_TypeDef *i2c;
switch (dev) {
#if I2C_0_EN
case I2C_0:
i2c = I2C_0_DEV;
break;
#endif
default:
return -1;
}
int res = _wait_ready(i2c);
if (res != 0) {
return res;
}
return _read_bytes(i2c, address, data, length, &err_flag[dev]);
}
static inline int _wait_ready(I2C_TypeDef *dev)
{
/* wait for device to be ready */
DEBUG("Wait for device to be ready\n");
int cnt = 0;
while ((dev->SR2 & I2C_SR2_BUSY) && cnt++ < I2C_MAX_LOOP_CNT) {}
if (cnt == I2C_MAX_LOOP_CNT) {
return -3;
}
return 0;
}
static int _read_bytes(I2C_TypeDef *i2c, uint8_t address, uint8_t *data, int length, uint8_t *err)
{
unsigned int state;
int i = 0;
int cnt = 0;
int res;
switch (length) {
case 1:
DEBUG("Send Slave address and wait for ADDR == 1\n");
res = _start(i2c, address, I2C_FLAG_READ, err);
if (res != 0) {
return res;
}
if (*err) {
return -3;
}
DEBUG("Set ACK = 0\n");
i2c->CR1 &= ~(I2C_CR1_ACK);
DEBUG("Clear ADDR and set STOP = 1\n");
state = irq_disable();
_clear_addr(i2c);
i2c->CR1 |= (I2C_CR1_STOP);
irq_restore(state);
DEBUG("Wait for RXNE == 1\n");
cnt = 0;
*err = 0;
while (!(i2c->SR1 & I2C_SR1_RXNE) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("Read received data\n");
*data = i2c->DR;
/* wait until STOP is cleared by hardware */
cnt = 0;
*err = 0;
while ((i2c->CR1 & I2C_CR1_STOP) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT) {
return -3;
}
/* reset ACK to be able to receive new data */
i2c->CR1 |= (I2C_CR1_ACK);
break;
case 2:
DEBUG("Send Slave address and wait for ADDR == 1\n");
res = _start(i2c, address, I2C_FLAG_READ, err);
if (res != 0) {
return res;
}
if (*err) {
return -3;
}
DEBUG("Set POS bit\n");
i2c->CR1 |= (I2C_CR1_POS | I2C_CR1_ACK);
DEBUG("Crit block: Clear ADDR bit and clear ACK flag\n");
state = irq_disable();
_clear_addr(i2c);
i2c->CR1 &= ~(I2C_CR1_ACK);
irq_restore(state);
DEBUG("Wait for transfer to be completed\n");
cnt = 0;
*err = 0;
while (!(i2c->SR1 & I2C_SR1_BTF) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("Crit block: set STOP and read first byte\n");
state = irq_disable();
i2c->CR1 |= (I2C_CR1_STOP);
data[0] = i2c->DR;
irq_restore(state);
DEBUG("read second byte\n");
data[1] = i2c->DR;
DEBUG("wait for STOP bit to be cleared again\n");
cnt = 0;
*err = 0;
while ((i2c->CR1 & I2C_CR1_STOP) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("reset POS = 0 and ACK = 1\n");
i2c->CR1 &= ~(I2C_CR1_POS);
i2c->CR1 |= (I2C_CR1_ACK);
break;
default:
DEBUG("Send Slave address and wait for ADDR == 1\n");
res = _start(i2c, address, I2C_FLAG_READ, err);
if (res != 0) {
return res;
}
_clear_addr(i2c);
while (i < (length - 3)) {
DEBUG("Wait until byte was received\n");
cnt = 0;
*err = 0;
while (!(i2c->SR1 & I2C_SR1_RXNE) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("Copy byte from DR\n");
data[i++] = i2c->DR;
}
DEBUG("Reading the last 3 bytes, waiting for BTF flag\n");
cnt = 0;
*err = 0;
while (!(i2c->SR1 & I2C_SR1_BTF) && cnt++ < I2C_MAX_LOOP_CNT && !(*err));
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("Disable ACK\n");
i2c->CR1 &= ~(I2C_CR1_ACK);
DEBUG("Crit block: set STOP and read N-2 byte\n");
state = irq_disable();
data[i++] = i2c->DR;
i2c->CR1 |= (I2C_CR1_STOP);
irq_restore(state);
DEBUG("Read N-1 byte\n");
data[i++] = i2c->DR;
cnt = 0;
*err = 0;
while (!(i2c->SR1 & I2C_SR1_RXNE) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("Read last byte\n");
data[i++] = i2c->DR;
DEBUG("wait for STOP bit to be cleared again\n");
cnt = 0;
*err = 0;
while ((i2c->CR1 & I2C_CR1_STOP) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("reset POS = 0 and ACK = 1\n");
i2c->CR1 &= ~(I2C_CR1_POS);
i2c->CR1 |= (I2C_CR1_ACK);
}
return length;
}
int i2c_read_reg(i2c_t dev, uint8_t address, uint8_t reg, void *data)
{
return i2c_read_regs(dev, address, reg, data, 1);
}
int i2c_read_regs(i2c_t dev, uint8_t address, uint8_t reg, void *data, int length)
{
I2C_TypeDef *i2c;
int res;
switch (dev) {
#if I2C_0_EN
case I2C_0:
i2c = I2C_0_DEV;
break;
#endif
default:
return -1;
}
/* send start condition and slave address */
DEBUG("Send slave address and clear ADDR flag\n");
res = _wait_ready(i2c);
if (res != 0) {
return res;
}
res = _start(i2c, address, I2C_FLAG_WRITE, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
_clear_addr(i2c);
DEBUG("Write reg into DR\n");
i2c->DR = reg;
DEBUG("Now start a read transaction\n");
return _read_bytes(i2c, address, data, length, &err_flag[dev]);
}
int i2c_write_byte(i2c_t dev, uint8_t address, uint8_t data)
{
return i2c_write_bytes(dev, address, &data, 1);
}
int i2c_write_bytes(i2c_t dev, uint8_t address, const void *data, int length)
{
I2C_TypeDef *i2c;
int res;
switch (dev) {
#if I2C_0_EN
case I2C_0:
i2c = I2C_0_DEV;
break;
#endif
default:
return -1;
}
/* start transmission and send slave address */
DEBUG("sending start sequence\n");
res = _wait_ready(i2c);
if (res != 0) {
return res;
}
res = _start(i2c, address, I2C_FLAG_WRITE, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
_clear_addr(i2c);
/* send out data bytes */
res = _write(i2c, data, length, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
/* end transmission */
DEBUG("Ending transmission\n");
res = _stop(i2c, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
DEBUG("STOP condition was send out\n");
return length;
}
int i2c_write_reg(i2c_t dev, uint8_t address, uint8_t reg, uint8_t data)
{
return i2c_write_regs(dev, address, reg, &data, 1);
}
int i2c_write_regs(i2c_t dev, uint8_t address, uint8_t reg, const void *data, int length)
{
I2C_TypeDef *i2c;
int res;
switch (dev) {
#if I2C_0_EN
case I2C_0:
i2c = I2C_0_DEV;
break;
#endif
default:
return -1;
}
/* start transmission and send slave address */
res = _wait_ready(i2c);
if (res != 0) {
return res;
}
res = _start(i2c, address, I2C_FLAG_WRITE, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
_clear_addr(i2c);
/* send register address and wait for complete transfer to be finished*/
res = _write(i2c, ®, 1, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
/* write data to register */
res = _write(i2c, data, length, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
/* finish transfer */
res = _stop(i2c, &err_flag[dev]);
if (res != 0) {
return res;
}
if (err_flag[dev]) {
return -3;
}
/* return number of bytes send */
return length;
}
void i2c_poweron(i2c_t dev)
{
switch (dev) {
#if I2C_0_EN
case I2C_0:
I2C_0_CLKEN();
break;
#endif
}
}
void i2c_poweroff(i2c_t dev)
{
int cnt = 0;
switch (dev) {
#if I2C_0_EN
case I2C_0:
while ((I2C_0_DEV->SR2 & I2C_SR2_BUSY) && cnt++ < I2C_MAX_LOOP_CNT) {}
I2C_0_CLKDIS();
break;
#endif
}
}
static int _start(I2C_TypeDef *dev, uint8_t address, uint8_t rw_flag, uint8_t *err)
{
int cnt = 0;
*err = 0;
/* generate start condition */
DEBUG("Generate start condition\n");
dev->CR1 |= I2C_CR1_START;
DEBUG("Wait for SB flag to be set\n");
while (!(dev->SR1 & I2C_SR1_SB) && cnt++ < I2C_MAX_LOOP_CNT && !(*err));
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
/* send address and read/write flag */
DEBUG("Send address\n");
dev->DR = (address << 1) | rw_flag;
/* clear ADDR flag by reading first SR1 and then SR2 */
DEBUG("Wait for ADDR flag to be set\n");
cnt = 0;
*err = 0;
while (!(dev->SR1 & I2C_SR1_ADDR) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT) {
return -3;
}
return 0;
}
static inline void _clear_addr(I2C_TypeDef *dev)
{
dev->SR1;
dev->SR2;
DEBUG("Cleared address\n");
}
static inline int _write(I2C_TypeDef *dev, const uint8_t *data, int length, uint8_t *err)
{
DEBUG("Looping through bytes\n");
for (int i = 0; i < length; i++) {
/* write data to data register */
dev->DR = data[i];
DEBUG("Written %i byte to data reg, now waiting for DR to be empty again\n", i);
/* wait for transfer to finish */
int cnt = 0;
*err = 0;
while (!(dev->SR1 & I2C_SR1_TXE) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT || *err) {
return -3;
}
DEBUG("DR is now empty again\n");
}
return 0;
}
static inline int _stop(I2C_TypeDef *dev, uint8_t *err)
{
/* make sure last byte was send */
DEBUG("Wait if last byte hasn't been sent\n");
int cnt = 0;
*err = 0;
while (!(dev->SR1 & I2C_SR1_BTF) && cnt++ < I2C_MAX_LOOP_CNT && !(*err)) {}
if (cnt == I2C_MAX_LOOP_CNT) {
return -3;
}
/* send STOP condition */
dev->CR1 |= I2C_CR1_STOP;
return 0;
}
static inline void i2c_irq_handler(i2c_t i2c_dev, I2C_TypeDef *dev)
{
unsigned volatile state = dev->SR1;
/* record and clear errors */
err_flag[i2c_dev] = (state >> 8);
dev->SR1 &= 0x00ff;
DEBUG("\n\n### I2C %d ERROR OCCURED ###\n", i2c_dev);
DEBUG("status: %08x\n", state);
if (state & I2C_SR1_OVR) {
DEBUG("OVR\n");
}
if (state & I2C_SR1_AF) {
DEBUG("AF\n");
}
if (state & I2C_SR1_ARLO) {
DEBUG("ARLO\n");
}
if (state & I2C_SR1_BERR) {
DEBUG("BERR\n");
}
if (state & I2C_SR1_PECERR) {
DEBUG("PECERR\n");
}
if (state & I2C_SR1_TIMEOUT) {
DEBUG("TIMEOUT\n");
}
if (state & I2C_SR1_SMBALERT) {
DEBUG("SMBALERT\n");
}
}
#if I2C_0_EN
void I2C_0_ERR_ISR(void)
{
i2c_irq_handler(I2C_0, I2C_0_DEV);
}
#endif
#endif /* I2C_NUMOF */