Spurious Interrupts Temporary fix 20180711 (#1625)

the 'eject' ERROR is and indication of an interrupt triggering without an source.  I am working to eliminate these serviceable interrupt.  This update increase stability on a HelTek Wifi Lora 32 board. with a SSD1306 OLED.  This update fixes a glaring error in the interrupt allocation code, the Interrupt mask was wrong.  I also dynamically adjust the FiFo thresholds based on Bus clockrate. The change to FiFo thresholds has reduced the number for 'eject' events.  I also change 'eject' from and ERROR to DEBUG.  An 'eject' event does not compromise i2c transmissions. It happens after a transaction has completed. 

Chuck.
This commit is contained in:
chuck todd 2018-07-12 07:18:26 -06:00 committed by Me No Dev
parent ddfeae90d0
commit 28a410dd50

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@ -491,6 +491,18 @@ static void IRAM_ATTR fillTxFifo(i2c_t * i2c)
if(!full || (a >= i2c->queueCount)) { // disable IRQ, the next dq will re-enable it
i2c->dev->int_ena.tx_fifo_empty=0;
if(!full) { // add a byte to keep spurious tx_empty int
uint8_t filler=i2c->dev->fifo_conf.tx_fifo_empty_thrhd;
if(filler >( 31 - i2c->dev->status_reg.tx_fifo_cnt)){
filler = ( 31 - i2c->dev->status_reg.tx_fifo_cnt);
}
while(filler > 0){
i2c->dev->fifo_data.val = 0xFE; // Just a dummy byte
filler--;
}
}
}
i2c->dev->int_clr.tx_fifo_empty=1;
@ -563,9 +575,9 @@ static void IRAM_ATTR i2cIsrExit(i2c_t * i2c,const uint32_t eventCode,bool Fatal
if(i2c->dq[i2c->queuePos].ctrl.mode == 1) {
emptyRxFifo(i2c); // grab last few characters
}
// log_d("raw=0x%05x status=0x%05x",i2c->dev->int_raw.val,i2c->dev->int_status.val);
i2c->dev->int_ena.val = 0; // shutdown interrupts
i2c->dev->int_clr.val = 0x1FFFF;
i2c->dev->int_clr.val = 0x1FFF;
i2c->stage = I2C_DONE;
i2c->exitCode = exitCode; //true eventcode
@ -586,12 +598,16 @@ static void IRAM_ATTR i2cIsrExit(i2c_t * i2c,const uint32_t eventCode,bool Fatal
static void IRAM_ATTR i2c_isr_handler_default(void* arg)
{
i2c_t* p_i2c = (i2c_t*) arg; // recover data
uint32_t activeInt = p_i2c->dev->int_status.val&0x1FFF;
uint32_t activeInt = p_i2c->dev->int_status.val&0x7FF;
//portBASE_TYPE HPTaskAwoken = pdFALSE,xResult;
if(p_i2c->stage==I2C_DONE) { //get Out
log_e("eject int=%p, ena=%p",activeInt,p_i2c->dev->int_ena.val);
if(!activeInt){ //spurious interrupt, possibly bus relate 20180711
log_d("raw=0x%05x status=0x%05x",p_i2c->dev->int_raw.val,p_i2c->dev->int_status.val);
}
if(p_i2c->stage==I2C_DONE) { //get Out, can't service, not configured
// this error is some kind of a race condition at high clock >400khz
// see #1588. it does not compromise i2c communications though, just
// a poke in the eye
log_d("eject raw=%p, int=%p",p_i2c->dev->int_raw.val,activeInt);
p_i2c->dev->int_ena.val = 0;
p_i2c->dev->int_clr.val = activeInt; //0x1FFF;
return;
@ -610,7 +626,6 @@ static void IRAM_ATTR i2c_isr_handler_default(void* arg)
intBuff[intPos[p_i2c->num]][2][p_i2c->num] = xTaskGetTickCountFromISR(); // when IRQ fired
#endif
//uint32_t oldInt =activeInt;
if (activeInt & I2C_TRANS_START_INT_ST_M) {
// p_i2c->byteCnt=0;
@ -871,11 +886,14 @@ i2c_err_t i2cProcQueue(i2c_t * i2c, uint32_t *readCount, uint16_t timeOutMillis)
f.rx_fifo_rst = 1; // fifo in reset
f.tx_fifo_rst = 1; // fifo in reset
f.nonfifo_en = 0; // use fifo mode
f.nonfifo_tx_thres =63;
// need to adjust threshold based on I2C clock rate, at 100k, 30 usually works,
// sometimes the emptyRx() actually moves 31 bytes
// it hasn't overflowed yet, I cannot tell if the new byte is added while
// emptyRX() is executing or before?
f.rx_fifo_full_thrhd = 30; // 30 bytes before INT is issued
// let i2cSetFrequency() set thrhds
// f.rx_fifo_full_thrhd = 30; // 30 bytes before INT is issued
// f.tx_fifo_empty_thrhd = 0;
f.fifo_addr_cfg_en = 0; // no directed access
i2c->dev->fifo_conf.val = f.val; // post them all
@ -936,9 +954,9 @@ i2c_err_t i2cProcQueue(i2c_t * i2c, uint32_t *readCount, uint16_t timeOutMillis)
ESP_INTR_FLAG_LOWMED; //< Low and medium prio interrupts. These can be handled in C.
if(i2c->num) {
ret = esp_intr_alloc_intrstatus(ETS_I2C_EXT1_INTR_SOURCE, flags, (uint32_t)&i2c->dev->int_status.val, 0x1FFF, &i2c_isr_handler_default,i2c, &i2c->intr_handle);
ret = esp_intr_alloc_intrstatus(ETS_I2C_EXT1_INTR_SOURCE, flags, (uint32_t)&i2c->dev->int_status.val, 0x7FF, &i2c_isr_handler_default,i2c, &i2c->intr_handle);
} else {
ret = esp_intr_alloc_intrstatus(ETS_I2C_EXT0_INTR_SOURCE, flags, (uint32_t)&i2c->dev->int_status.val, 0x1FFF, &i2c_isr_handler_default,i2c, &i2c->intr_handle);
ret = esp_intr_alloc_intrstatus(ETS_I2C_EXT0_INTR_SOURCE, flags, (uint32_t)&i2c->dev->int_status.val, 0x7FF, &i2c_isr_handler_default,i2c, &i2c->intr_handle);
}
if(ret!=ESP_OK) {
@ -1326,12 +1344,23 @@ i2c_err_t i2cSetFrequency(i2c_t * i2c, uint32_t clk_speed)
if(i2c == NULL) {
return I2C_ERROR_DEV;
}
I2C_FIFO_CONF_t f;
uint32_t period = (APB_CLK_FREQ/clk_speed) / 2;
uint32_t halfPeriod = period/2;
uint32_t quarterPeriod = period/4;
I2C_MUTEX_LOCK();
// Adjust Fifo thresholds based on frequency
f.val = i2c->dev->fifo_conf.val;
uint32_t a = (clk_speed / 50000L )+1;
if (a > 24) a=24;
f.rx_fifo_full_thrhd = 32 - a;
f.tx_fifo_empty_thrhd = a;
i2c->dev->fifo_conf.val = f.val; // set thresholds
log_v("threshold=%d",a);
//the clock num during SCL is low level
i2c->dev->scl_low_period.period = period;
//the clock num during SCL is high level