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esp-open-rtos/extras/i2c/i2c.c
Sakari Kapanen 4a1b600be4 i2c: improve timing 
Look-up tables were used for determining the delay loop counts before.
Based on these hand-tuned values, the loop overhead was estimated for
each option -- 80 and 160 MHz, fast and slow GPIO access. Instead of the
great number of tunable parameters one now only has to tune the overhead
values if the code is changed.

Functions were added to the API which allow setting an arbitrary
frequency. API backward compatibility is retained.

i2c: fix potential overflow situation
2018-02-27 23:47:16 +02:00

465 lines
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/*
* The MIT License (MIT)
*
* Copyright (c) 2015 Johan Kanflo (github.com/kanflo)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "i2c.h"
#include <esp8266.h>
#include <espressif/esp_system.h>
#include <FreeRTOS.h>
#include <task.h>
//#define I2C_DEBUG true
#ifdef I2C_DEBUG
#define debug(fmt, ...) printf("%s: " fmt "\n", "I2C", ## __VA_ARGS__)
#else
#define debug(fmt, ...)
#endif
// Delay loop takes four CPU clock cycles per round
#define DELAY_LOOPS_PER_US_160MHZ 40
// The value for 80 MHz is half the above
// Constant overhead per I2C clock cycle in terms of delay loop rounds.
// If timing is changed by some code change, these will require tuning.
#if I2C_USE_GPIO16 == 1
#define DELAY_OVERHEAD_80MHZ 18
#define DELAY_OVERHEAD_160MHZ 20
#else
#define DELAY_OVERHEAD_80MHZ 12
#define DELAY_OVERHEAD_160MHZ 14
#endif
// Bus settings
typedef struct i2c_bus_description
{
#if I2C_USE_GPIO16 == 1
uint8_t g_scl_pin; // SCL pin
uint8_t g_sda_pin; // SDA pin
#else
uint32_t g_scl_mask; // SCL pin mask
uint32_t g_sda_mask; // SDA pin mask
#endif
uint8_t delay_80;
uint8_t delay_160;
uint8_t delay;
bool started;
bool flag;
bool force;
uint32_t clk_stretch;
} i2c_bus_description_t;
static i2c_bus_description_t i2c_bus[I2C_MAX_BUS];
inline bool i2c_status(uint8_t bus)
{
return i2c_bus[bus].started;
}
static uint32_t freq_t_to_hz(i2c_freq_t freq)
{
switch (freq)
{
case I2C_FREQ_80K: return 80000;
case I2C_FREQ_100K: return 100000;
case I2C_FREQ_400K: return 400000;
case I2C_FREQ_500K: return 500000;
case I2C_FREQ_600K: return 600000;
case I2C_FREQ_800K: return 800000;
case I2C_FREQ_1000K: return 1000000;
case I2C_FREQ_1300K: return 1300000;
}
return 80000;
}
int i2c_init(uint8_t bus, uint8_t scl_pin, uint8_t sda_pin, i2c_freq_t freq)
{
return i2c_init_hz(bus, scl_pin, sda_pin, freq_t_to_hz(freq));
}
int i2c_init_hz(uint8_t bus, uint8_t scl_pin, uint8_t sda_pin, uint32_t freq)
{
if (bus >= I2C_MAX_BUS) {
debug("Invalid bus");
return -EINVAL;
}
#if I2C_USE_GPIO16 == 1
const int I2C_MAX_PIN = 16;
#else
const int I2C_MAX_PIN = 15;
#endif
if (scl_pin > I2C_MAX_PIN || sda_pin > I2C_MAX_PIN)
{
debug("Invalid GPIO number. All pins must be less than or equal to %d",
I2C_MAX_PIN);
return -EINVAL;
}
i2c_bus[bus].started = false;
i2c_bus[bus].flag = false;
#if I2C_USE_GPIO16 == 1
i2c_bus[bus].g_scl_pin = scl_pin;
i2c_bus[bus].g_sda_pin = sda_pin;
#else
i2c_bus[bus].g_scl_mask = BIT(scl_pin);
i2c_bus[bus].g_sda_mask = BIT(sda_pin);
#endif
i2c_bus[bus].clk_stretch = I2C_DEFAULT_CLK_STRETCH;
// Just to prevent these pins floating too much if not connected.
gpio_set_pullup(scl_pin, 1, 1);
gpio_set_pullup(sda_pin, 1, 1);
gpio_enable(scl_pin, GPIO_OUT_OPEN_DRAIN);
gpio_enable(sda_pin, GPIO_OUT_OPEN_DRAIN);
// I2C bus idle state.
gpio_write(scl_pin, 1);
gpio_write(sda_pin, 1);
// Inform user if the desired frequency is not supported.
if (i2c_set_frequency_hz(bus, freq) != 0) {
debug("Frequency not supported");
return -ENOTSUP;
}
return 0;
}
int i2c_set_frequency(uint8_t bus, i2c_freq_t freq)
{
return i2c_set_frequency_hz(bus, freq_t_to_hz(freq));
}
int i2c_set_frequency_hz(uint8_t bus, uint32_t freq)
{
if (freq == 0) return -EINVAL;
uint32_t tick_count = (1000000UL * DELAY_LOOPS_PER_US_160MHZ) / (2 * freq);
bool not_ok = false;
int32_t delay_80 = tick_count / 2 - DELAY_OVERHEAD_80MHZ;
if (delay_80 > 255) {
delay_80 = 255;
not_ok = true;
} else if (delay_80 < 0) {
delay_80 = 0;
not_ok = true;
}
int32_t delay_160 = tick_count - DELAY_OVERHEAD_160MHZ;
if (delay_160 > 255) {
delay_160 = 255;
not_ok = true;
} else if (delay_160 < 0) {
delay_160 = 0;
not_ok = true;
}
i2c_bus[bus].delay_80 = delay_80;
i2c_bus[bus].delay_160 = delay_160;
return not_ok ? -EINVAL : 0;
}
void i2c_set_clock_stretch(uint8_t bus, uint32_t clk_stretch)
{
i2c_bus[bus].clk_stretch = clk_stretch;
}
static inline void i2c_delay(uint8_t bus)
{
uint32_t delay = i2c_bus[bus].delay;
__asm volatile (
"1: addi %0, %0, -1" "\n"
"bnez %0, 1b" "\n"
: "=a" (delay) : "0" (delay));
}
static inline bool read_scl(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
return gpio_read(i2c_bus[bus].g_scl_pin);
#else
return GPIO.IN & i2c_bus[bus].g_scl_mask;
#endif
}
static inline bool read_sda(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
return gpio_read(i2c_bus[bus].g_sda_pin);
#else
return GPIO.IN & i2c_bus[bus].g_sda_mask;
#endif
}
// Actively drive SCL signal low
static inline void clear_scl(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
gpio_write(i2c_bus[bus].g_scl_pin, 0);
#else
GPIO.OUT_CLEAR = i2c_bus[bus].g_scl_mask;
#endif
}
// Actively drive SDA signal low
static inline void clear_sda(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
gpio_write(i2c_bus[bus].g_sda_pin, 0);
#else
GPIO.OUT_CLEAR = i2c_bus[bus].g_sda_mask;
#endif
}
static inline void set_scl(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
gpio_write(i2c_bus[bus].g_scl_pin, 1);
#else
GPIO.OUT_SET = i2c_bus[bus].g_scl_mask;
#endif
}
static inline void set_sda(uint8_t bus)
{
#if I2C_USE_GPIO16 == 1
gpio_write(i2c_bus[bus].g_sda_pin, 1);
#else
GPIO.OUT_SET = i2c_bus[bus].g_sda_mask;
#endif
}
// Output start condition
void i2c_start(uint8_t bus)
{
if (sdk_system_get_cpu_freq() == SYS_CPU_160MHZ)
i2c_bus[bus].delay = i2c_bus[bus].delay_160;
else
i2c_bus[bus].delay = i2c_bus[bus].delay_80;
if (i2c_bus[bus].started) { // if started, do a restart cond
// Set SDA to 1
set_sda(bus);
i2c_delay(bus);
uint32_t clk_stretch = i2c_bus[bus].clk_stretch;
set_scl(bus);
while (read_scl(bus) == 0 && clk_stretch--)
;
// Repeated start setup time, minimum 4.7us
i2c_delay(bus);
}
i2c_bus[bus].started = true;
set_sda(bus);
if (read_sda(bus) == 0) {
debug("arbitration lost in i2c_start from bus %u", bus);
}
// SCL is high, set SDA from 1 to 0.
clear_sda(bus);
i2c_delay(bus);
clear_scl(bus);
}
// Output stop condition
bool i2c_stop(uint8_t bus)
{
uint32_t clk_stretch = i2c_bus[bus].clk_stretch;
// Set SDA to 0
clear_sda(bus);
i2c_delay(bus);
// Clock stretching
set_scl(bus);
while (read_scl(bus) == 0 && clk_stretch--)
;
// Stop bit setup time, minimum 4us
i2c_delay(bus);
// SCL is high, set SDA from 0 to 1
set_sda(bus);
// additional delay before testing SDA value to avoid wrong state
i2c_delay(bus);
if (read_sda(bus) == 0) {
debug("arbitration lost in i2c_stop from bus %u", bus);
}
i2c_delay(bus);
if (!i2c_bus[bus].started) {
debug("bus %u link was break!", bus);
return false; // If bus was stop in other way, the current transmission Failed
}
i2c_bus[bus].started = false;
return true;
}
// Write a bit to I2C bus
static void i2c_write_bit(uint8_t bus, bool bit)
{
uint32_t clk_stretch = i2c_bus[bus].clk_stretch;
if (bit) {
set_sda(bus);
} else {
clear_sda(bus);
}
i2c_delay(bus);
// Clock stretching
set_scl(bus);
while (read_scl(bus) == 0 && clk_stretch--)
;
// SCL is high, now data is valid
// If SDA is high, check that nobody else is driving SDA
if (bit && read_sda(bus) == 0) {
debug("arbitration lost in i2c_write_bit from bus %u", bus);
}
i2c_delay(bus);
clear_scl(bus);
}
// Read a bit from I2C bus
static bool i2c_read_bit(uint8_t bus)
{
uint32_t clk_stretch = i2c_bus[bus].clk_stretch;
bool bit;
// Let the slave drive data
set_sda(bus);
i2c_delay(bus);
set_scl(bus);
// Clock stretching
while (read_scl(bus) == 0 && clk_stretch--)
;
// SCL is high, now data is valid
bit = read_sda(bus);
i2c_delay(bus);
clear_scl(bus);
return bit;
}
bool i2c_write(uint8_t bus, uint8_t byte)
{
bool nack;
uint8_t bit;
for (bit = 0; bit < 8; bit++) {
i2c_write_bit(bus, (byte & 0x80) != 0);
byte <<= 1;
}
nack = i2c_read_bit(bus);
return !nack;
}
uint8_t i2c_read(uint8_t bus, bool ack)
{
uint8_t byte = 0;
uint8_t bit;
for (bit = 0; bit < 8; bit++) {
byte = ((byte << 1)) | (i2c_read_bit(bus));
}
i2c_write_bit(bus, ack);
return byte;
}
void i2c_force_bus(uint8_t bus, bool state)
{
i2c_bus[bus].force = state;
}
static int i2c_bus_test(uint8_t bus)
{
taskENTER_CRITICAL(); // To prevent task swaping after checking flag and before set it!
bool status = i2c_bus[bus].flag; // get current status
if (i2c_bus[bus].force) {
i2c_bus[bus].flag = true; // force bus on
taskEXIT_CRITICAL();
if (status)
i2c_stop(bus); //Bus was busy, stop it.
}
else {
if (status) {
taskEXIT_CRITICAL();
debug("busy");
taskYIELD(); // If bus busy, change task to try finish last com.
return -EBUSY; // If bus busy, inform user
}
else {
i2c_bus[bus].flag = true; // Set Bus busy
taskEXIT_CRITICAL();
}
}
return 0;
}
int i2c_slave_write(uint8_t bus, uint8_t slave_addr, const uint8_t *data, const uint8_t *buf, uint32_t len)
{
if (i2c_bus_test(bus))
return -EBUSY;
i2c_start(bus);
if (!i2c_write(bus, slave_addr << 1))
goto error;
if (data != NULL)
if (!i2c_write(bus, *data))
goto error;
while (len--) {
if (!i2c_write(bus, *buf++))
goto error;
}
if (!i2c_stop(bus))
goto error;
i2c_bus[bus].flag = false; // Bus free
return 0;
error:
debug("Bus %u Write Error", bus);
i2c_stop(bus);
i2c_bus[bus].flag = false; // Bus free
return -EIO;
}
int i2c_slave_read(uint8_t bus, uint8_t slave_addr, const uint8_t *data, uint8_t *buf, uint32_t len)
{
if (i2c_bus_test(bus))
return -EBUSY;
if (data != NULL) {
i2c_start(bus);
if (!i2c_write(bus, slave_addr << 1))
goto error;
if (!i2c_write(bus, *data))
goto error;
}
i2c_start(bus);
if (!i2c_write(bus, slave_addr << 1 | 1)) // Slave address + read
goto error;
while(len) {
*buf = i2c_read(bus, len == 1);
buf++;
len--;
}
if (!i2c_stop(bus))
goto error;
i2c_bus[bus].flag = false; // Bus free
return 0;
error:
debug("Read Error");
i2c_stop(bus);
i2c_bus[bus].flag = false; // Bus free
return -EIO;
}
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