Fix I2C recovery ESP32 esp-idf (#2438)

Co-authored-by: Maurice Makaay <mmakaay1@xs4all.net>
This commit is contained in:
Maurice Makaay 2021-10-04 12:33:25 +02:00 committed by GitHub
parent 49f46a7cdd
commit 5c06cd8eb3
No known key found for this signature in database
GPG key ID: 4AEE18F83AFDEB23
3 changed files with 137 additions and 44 deletions

View file

@ -12,6 +12,7 @@ static const char *const TAG = "i2c.arduino";
void ArduinoI2CBus::setup() { void ArduinoI2CBus::setup() {
recover_(); recover_();
#ifdef USE_ESP32 #ifdef USE_ESP32
static uint8_t next_bus_num = 0; static uint8_t next_bus_num = 0;
if (next_bus_num == 0) if (next_bus_num == 0)
@ -109,11 +110,19 @@ ErrorCode ArduinoI2CBus::writev(uint8_t address, WriteBuffer *buffers, size_t cn
void ArduinoI2CBus::recover_() { void ArduinoI2CBus::recover_() {
ESP_LOGI(TAG, "Performing I2C bus recovery"); ESP_LOGI(TAG, "Performing I2C bus recovery");
// Activate the pull up resistor on the SCL pin. This should make the // For the upcoming operations, target for a 100kHz toggle frequency.
// signal on the line HIGH. If SCL is pulled low on the I2C bus however, // This is the maximum frequency for I2C running in standard-mode.
// then some device is interfering with the SCL line. In that case, // The actual frequency will be lower, because of the additional
// the I2C bus cannot be recovered. // function calls that are done, but that is no problem.
const auto half_period_usec = 1000000 / 100000 / 2;
// Activate input and pull up resistor for the SCL pin.
pinMode(scl_pin_, INPUT_PULLUP); // NOLINT pinMode(scl_pin_, INPUT_PULLUP); // NOLINT
// This should make the signal on the line HIGH. If SCL is pulled low
// on the I2C bus however, then some device is interfering with the SCL
// line. In that case, the I2C bus cannot be recovered.
delayMicroseconds(half_period_usec);
if (digitalRead(scl_pin_) == LOW) { // NOLINT if (digitalRead(scl_pin_) == LOW) { // NOLINT
ESP_LOGE(TAG, "Recovery failed: SCL is held LOW on the I2C bus"); ESP_LOGE(TAG, "Recovery failed: SCL is held LOW on the I2C bus");
recovery_result_ = RECOVERY_FAILED_SCL_LOW; recovery_result_ = RECOVERY_FAILED_SCL_LOW;
@ -125,25 +134,13 @@ void ArduinoI2CBus::recover_() {
// device that held the bus LOW should release it sometime within // device that held the bus LOW should release it sometime within
// those nine clocks." // those nine clocks."
// We don't really have to detect if SDA is stuck low. We'll simply send // We don't really have to detect if SDA is stuck low. We'll simply send
// nine clock pulses here, just in case SDA is stuck. // nine clock pulses here, just in case SDA is stuck. Actual checks on
// the SDA line status will be done after the clock pulses.
// Use a 100kHz toggle frequency (i.e. the maximum frequency for I2C // Make sure that switching to output mode will make SCL low, just in
// running in standard-mode). The resulting frequency will be lower, // case other code has setup the pin for a HIGH signal.
// because of the additional function calls that are done, but that
// is no problem.
const auto half_period_usec = 1000000 / 100000 / 2;
// Make sure that switching to mode OUTPUT will make SCL low, just in
// case other code has setup the pin to output a HIGH signal.
digitalWrite(scl_pin_, LOW); // NOLINT digitalWrite(scl_pin_, LOW); // NOLINT
// Activate the pull up resistor for SDA, so after the clock pulse cycle
// we can verify if SDA is pulled high. Also make sure that switching to
// mode OUTPUT will make SDA low.
pinMode(sda_pin_, INPUT_PULLUP); // NOLINT
digitalWrite(sda_pin_, LOW); // NOLINT
ESP_LOGI(TAG, "Sending 9 clock pulses to drain any stuck device output");
delayMicroseconds(half_period_usec); delayMicroseconds(half_period_usec);
for (auto i = 0; i < 9; i++) { for (auto i = 0; i < 9; i++) {
// Release pull up resistor and switch to output to make the signal LOW. // Release pull up resistor and switch to output to make the signal LOW.
@ -171,6 +168,11 @@ void ArduinoI2CBus::recover_() {
} }
} }
// Activate input and pull resistor for the SDA pin, so we can verify
// that SDA is pulled HIGH in the following step.
pinMode(sda_pin_, INPUT_PULLUP); // NOLINT
digitalWrite(sda_pin_, LOW); // NOLINT
// By now, any stuck device ought to have sent all remaining bits of its // By now, any stuck device ought to have sent all remaining bits of its
// transation, meaning that it should have freed up the SDA line, resulting // transation, meaning that it should have freed up the SDA line, resulting
// in SDA being pulled up. // in SDA being pulled up.
@ -191,10 +193,9 @@ void ArduinoI2CBus::recover_() {
// out of this state. // out of this state.
// SCL and SDA are already high at this point, so we can generate a START // SCL and SDA are already high at this point, so we can generate a START
// condition by making the SDA signal LOW. // condition by making the SDA signal LOW.
ESP_LOGI(TAG, "Generate START condition to reset bus logic of I2C devices"); delayMicroseconds(half_period_usec);
pinMode(sda_pin_, INPUT); // NOLINT pinMode(sda_pin_, INPUT); // NOLINT
pinMode(sda_pin_, OUTPUT); // NOLINT pinMode(sda_pin_, OUTPUT); // NOLINT
delayMicroseconds(half_period_usec);
// From the specification: // From the specification:
// "A START condition immediately followed by a STOP condition (void // "A START condition immediately followed by a STOP condition (void
@ -202,7 +203,7 @@ void ArduinoI2CBus::recover_() {
// operate properly under this condition." // operate properly under this condition."
// Finally, we'll bring the I2C bus into a starting state by generating // Finally, we'll bring the I2C bus into a starting state by generating
// a STOP condition. // a STOP condition.
ESP_LOGI(TAG, "Generate STOP condition to finalize recovery"); delayMicroseconds(half_period_usec);
pinMode(sda_pin_, INPUT); // NOLINT pinMode(sda_pin_, INPUT); // NOLINT
pinMode(sda_pin_, INPUT_PULLUP); // NOLINT pinMode(sda_pin_, INPUT_PULLUP); // NOLINT

View file

@ -43,6 +43,17 @@ void IDFI2CBus::dump_config() {
ESP_LOGCONFIG(TAG, " SDA Pin: GPIO%u", this->sda_pin_); ESP_LOGCONFIG(TAG, " SDA Pin: GPIO%u", this->sda_pin_);
ESP_LOGCONFIG(TAG, " SCL Pin: GPIO%u", this->scl_pin_); ESP_LOGCONFIG(TAG, " SCL Pin: GPIO%u", this->scl_pin_);
ESP_LOGCONFIG(TAG, " Frequency: %u Hz", this->frequency_); ESP_LOGCONFIG(TAG, " Frequency: %u Hz", this->frequency_);
switch (this->recovery_result_) {
case RECOVERY_COMPLETED:
ESP_LOGCONFIG(TAG, " Recovery: bus successfully recovered");
break;
case RECOVERY_FAILED_SCL_LOW:
ESP_LOGCONFIG(TAG, " Recovery: failed, SCL is held low on the bus");
break;
case RECOVERY_FAILED_SDA_LOW:
ESP_LOGCONFIG(TAG, " Recovery: failed, SDA is held low on the bus");
break;
}
if (this->scan_) { if (this->scan_) {
ESP_LOGI(TAG, "Scanning i2c bus for active devices..."); ESP_LOGI(TAG, "Scanning i2c bus for active devices...");
uint8_t found = 0; uint8_t found = 0;
@ -144,39 +155,113 @@ ErrorCode IDFI2CBus::writev(uint8_t address, WriteBuffer *buffers, size_t cnt) {
return ERROR_OK; return ERROR_OK;
} }
/// Perform I2C bus recovery, see:
/// https://www.nxp.com/docs/en/user-guide/UM10204.pdf
/// https://www.analog.com/media/en/technical-documentation/application-notes/54305147357414AN686_0.pdf
void IDFI2CBus::recover_() { void IDFI2CBus::recover_() {
// Perform I2C bus recovery, see ESP_LOGI(TAG, "Performing I2C bus recovery");
// https://www.analog.com/media/en/technical-documentation/application-notes/54305147357414AN686_0.pdf
// or see the linux kernel implementation, e.g.
// https://elixir.bootlin.com/linux/v5.14.6/source/drivers/i2c/i2c-core-base.c#L200
// try to get about 100kHz toggle frequency
const auto half_period_usec = 1000000 / 100000 / 2;
const auto recover_scl_periods = 9;
const gpio_num_t scl_pin = static_cast<gpio_num_t>(scl_pin_); const gpio_num_t scl_pin = static_cast<gpio_num_t>(scl_pin_);
const gpio_num_t sda_pin = static_cast<gpio_num_t>(sda_pin_);
// configure scl as output // For the upcoming operations, target for a 60kHz toggle frequency.
gpio_config_t conf{}; // 1000kHz is the maximum frequency for I2C running in standard-mode,
conf.pin_bit_mask = 1ULL << static_cast<uint32_t>(scl_pin_); // but lower frequencies are not a problem.
conf.mode = GPIO_MODE_OUTPUT; // Note: the timing that is used here is chosen manually, to get
conf.pull_up_en = GPIO_PULLUP_DISABLE; // results that are close to the timing that can be archieved by the
conf.pull_down_en = GPIO_PULLDOWN_DISABLE; // implementation for the Arduino framework.
conf.intr_type = GPIO_INTR_DISABLE; const auto half_period_usec = 7;
gpio_config(&conf); // Configure SCL pin for open drain input/output, with a pull up resistor.
// set scl high
gpio_set_level(scl_pin, 1); gpio_set_level(scl_pin, 1);
gpio_config_t scl_config{};
scl_config.pin_bit_mask = 1ULL << scl_pin_;
scl_config.mode = GPIO_MODE_INPUT_OUTPUT_OD;
scl_config.pull_up_en = GPIO_PULLUP_ENABLE;
scl_config.pull_down_en = GPIO_PULLDOWN_DISABLE;
scl_config.intr_type = GPIO_INTR_DISABLE;
gpio_config(&scl_config);
// in total generate 9 falling-rising edges // Configure SDA pin for open drain input/output, with a pull up resistor.
for (auto i = 0; i < recover_scl_periods; i++) { gpio_set_level(sda_pin, 1);
gpio_config_t sda_conf{};
sda_conf.pin_bit_mask = 1ULL << sda_pin_;
sda_conf.mode = GPIO_MODE_INPUT_OUTPUT_OD;
sda_conf.pull_up_en = GPIO_PULLUP_ENABLE;
sda_conf.pull_down_en = GPIO_PULLDOWN_DISABLE;
sda_conf.intr_type = GPIO_INTR_DISABLE;
gpio_config(&sda_conf);
// If SCL is pulled low on the I2C bus, then some device is interfering
// with the SCL line. In that case, the I2C bus cannot be recovered.
delayMicroseconds(half_period_usec); delayMicroseconds(half_period_usec);
if (gpio_get_level(scl_pin) == 0) {
ESP_LOGE(TAG, "Recovery failed: SCL is held LOW on the I2C bus");
recovery_result_ = RECOVERY_FAILED_SCL_LOW;
return;
}
// From the specification:
// "If the data line (SDA) is stuck LOW, send nine clock pulses. The
// device that held the bus LOW should release it sometime within
// those nine clocks."
// We don't really have to detect if SDA is stuck low. We'll simply send
// nine clock pulses here, just in case SDA is stuck. Actual checks on
// the SDA line status will be done after the clock pulses.
for (auto i = 0; i < 9; i++) {
gpio_set_level(scl_pin, 0); gpio_set_level(scl_pin, 0);
delayMicroseconds(half_period_usec); delayMicroseconds(half_period_usec);
gpio_set_level(scl_pin, 1); gpio_set_level(scl_pin, 1);
delayMicroseconds(half_period_usec);
// When SCL is kept LOW at this point, we might be looking at a device
// that applies clock stretching. Wait for the release of the SCL line,
// but not forever. There is no specification for the maximum allowed
// time. We'll stick to 500ms here.
auto wait = 20;
while (wait-- && gpio_get_level(scl_pin) == 0) {
delay(25);
}
if (gpio_get_level(scl_pin) == 0) {
ESP_LOGE(TAG, "Recovery failed: SCL is held LOW during clock pulse cycle");
recovery_result_ = RECOVERY_FAILED_SCL_LOW;
return;
}
} }
// By now, any stuck device ought to have sent all remaining bits of its
// transation, meaning that it should have freed up the SDA line, resulting
// in SDA being pulled up.
if (gpio_get_level(sda_pin) == 0) {
ESP_LOGE(TAG, "Recovery failed: SDA is held LOW after clock pulse cycle");
recovery_result_ = RECOVERY_FAILED_SDA_LOW;
return;
}
// From the specification:
// "I2C-bus compatible devices must reset their bus logic on receipt of
// a START or repeated START condition such that they all anticipate
// the sending of a target address, even if these START conditions are
// not positioned according to the proper format."
// While the 9 clock pulses from above might have drained all bits of a
// single byte within a transaction, a device might have more bytes to
// transmit. So here we'll generate a START condition to snap the device
// out of this state.
// SCL and SDA are already high at this point, so we can generate a START
// condition by making the SDA signal LOW.
delayMicroseconds(half_period_usec); delayMicroseconds(half_period_usec);
gpio_set_level(sda_pin, 0);
// From the specification:
// "A START condition immediately followed by a STOP condition (void
// message) is an illegal format. Many devices however are designed to
// operate properly under this condition."
// Finally, we'll bring the I2C bus into a starting state by generating
// a STOP condition.
delayMicroseconds(half_period_usec);
gpio_set_level(sda_pin, 1);
recovery_result_ = RECOVERY_COMPLETED;
} }
} // namespace i2c } // namespace i2c

View file

@ -9,6 +9,12 @@
namespace esphome { namespace esphome {
namespace i2c { namespace i2c {
enum RecoveryCode {
RECOVERY_FAILED_SCL_LOW,
RECOVERY_FAILED_SDA_LOW,
RECOVERY_COMPLETED,
};
class IDFI2CBus : public I2CBus, public Component { class IDFI2CBus : public I2CBus, public Component {
public: public:
void setup() override; void setup() override;
@ -26,6 +32,7 @@ class IDFI2CBus : public I2CBus, public Component {
private: private:
void recover_(); void recover_();
RecoveryCode recovery_result_;
protected: protected:
i2c_port_t port_; i2c_port_t port_;