Ejemplo n.º 1
0
static inline void PPRZ_I2C_SEND_START(struct i2c_periph *periph)
{
  uint32_t i2c = (uint32_t) periph->reg_addr;

  // Reset the buffer pointer to the first byte
  periph->idx_buf = 0;

#ifdef I2C_DEBUG_LED
  LED_SHOW_ACTIVE_BITS(regs);

  LED2_ON();
  LED1_ON();
  LED1_OFF();
  LED1_ON();
  LED1_OFF();
  LED1_ON();
  LED1_OFF();
  LED2_OFF();
#endif

  // Enable Error IRQ, Event IRQ but disable Buffer IRQ
  i2c_enable_interrupt(i2c, I2C_CR2_ITERREN);
  i2c_enable_interrupt(i2c, I2C_CR2_ITEVTEN);
  i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);

  // Issue a new start
  i2c_nack_current(i2c);
  i2c_disable_ack(i2c);
  i2c_clear_stop(i2c);
  i2c_peripheral_enable(i2c);
  i2c_send_start(i2c);
  periph->status = I2CStartRequested;

}
Ejemplo n.º 2
0
// Doc ID 13902 Rev 11 p 714/1072
// Transfer Sequence Diagram for Master Receiver for N=1
static inline enum STMI2CSubTransactionStatus stmi2c_read1(uint32_t i2c, struct i2c_periph *periph, struct i2c_transaction *trans)
{
  uint16_t SR1 = I2C_SR1(i2c);

  // Start Condition Was Just Generated
  if (BIT_X_IS_SET_IN_REG( I2C_SR1_SB, SR1 ) )
  {
    i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);
    i2c_send_data(i2c, trans->slave_addr | 0x01);

    // Document the current Status
    periph->status = I2CAddrRdSent;
  }
  // Address Was Sent
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_ADDR, SR1) )
  {
    // First Clear the ACK bit: after the next byte we do not want new bytes
    i2c_nack_current(i2c);
    i2c_disable_ack(i2c);

    // --- next to steps MUST be executed together to avoid missing the stop
    __I2C_REG_CRITICAL_ZONE_START;

    // Only after setting ACK, read SR2 to clear the ADDR (next byte will start arriving)
    uint16_t SR2 __attribute__ ((unused)) = I2C_SR2(i2c);

    // Schedule a Stop
    PPRZ_I2C_SEND_STOP(i2c);

    __I2C_REG_CRITICAL_ZONE_STOP;
    // --- end of critical zone -----------

    // Enable the RXNE: it will trigger as soon as the 1 byte is received to get the result
    i2c_enable_interrupt(i2c, I2C_CR2_ITBUFEN);

    // Document the current Status
    periph->status = I2CReadingLastByte;
  }
  // As soon as there is 1 byte ready to read, we have our byte
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_RxNE, SR1) )
  {
    i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);
    trans->buf[0] = I2C_DR(i2c);

    // We got all the results (stop condition might still be in progress but this is the last interrupt)
    trans->status = I2CTransSuccess;

    // Document the current Status:
    // -the stop was actually already requested in the previous step
    periph->status = I2CStopRequested;

    return STMI2C_SubTra_Ready_StopRequested;
  }
  else // Event Logic Error
  {
    return STMI2C_SubTra_Error;
  }

  return STMI2C_SubTra_Busy;
}
Ejemplo n.º 3
0
int i2c_master_recv_data(unsigned int addr,
			unsigned char *data, unsigned int len)
{
	unsigned int i = 0;
	int ret = 0;

	ret = i2c_set_master();	// get iic bus, as bus master;
	if (ret) {
		putstring("\nget i2c bus error\n");
		return ret;	// error while getting bus
	}

	i2c_enable_irq();
	i2c_message_start(addr, 1);
	while (1) {
		i++;
		if (i == len) {		// last byte
			i2c_disable_ack();
			break;
		}
		*data++ = IICDS;
		IICCON &= ~(1 << 4);	// resume trasmit
		// TODO dealy ??
		for (ret = 0; ret < 30; ret++) ;	// setup time
	}

	/* last byte */
	*data++ = IICDS;
	IICCON &= ~(1 << 4);	// resume trasmit

	// TODO dealy ??
	for (ret = 0; ret < 30; ret++) ; // setup time
	return len;
}
Ejemplo n.º 4
0
/**
 * @brief Reads multiple 8-bit registers from an I2C slave
 * @param[in] slaveId The slave device ID
 * @param[in] startRegisterAddress The first register address
 * @param[in] registerCount The number of registers to read; Must be greater than or equal to two.
 * @param[out] buffer The buffer to write into
 * @return 0 is successful, 1 if not
 */
static int i2c_read_registers_internal(register uint8_t slaveId, register uint8_t startRegisterAddress, register uint8_t registerCount, uint8_t *const buffer){
  if(registerCount < 2)
    return -1;
	
	/* loop while the bus is still busy */
	i2c_wait_while_busy();
	
	/* send I2C start signal and set write direction, also enables ACK */
	i2c_send_start();
	
	/* send the slave address and wait for the I2C bus operation to complete */
	i2c_send_byte(I2C_WRITE_ADDRESS(slaveId));
	
	/* send the register address */
	i2c_send_byte(startRegisterAddress);
	
	/* signal a repeated start condition */
	i2c_send_repeated_start();

	/* send the read address */
	i2c_send_byte(I2C_READ_ADDRESS(slaveId));
	
	/* switch to receive mode and assume more than one register */
	i2c_enter_receive_mode_with_ack();
	
	/* read a dummy byte to drive the clock */
	i2c_read_dummy_byte();
	
	/* for all remaining bytes, read */
	--registerCount;
	uint8_t index = 0;
	while (--registerCount > 0)
	{
		/* fetch and store value */
		register uint8_t value = I2C0->D;
		buffer[index++] = value;
		
		/* wait for completion */
		i2c_wait();
	}
	
	/* disable ACK and read second-to-last byte */
	i2c_disable_ack();
	
	/* fetch and store value */
	buffer[index++] = I2C0->D;
	
	/* wait for completion */
	i2c_wait();
	
	/* stop signal */
	i2c_send_stop();
	
	/* fetch the last received byte */
	buffer[index++] = I2C0->D; 
  
  return 0;
}
Ejemplo n.º 5
0
static uint32_t i2c_read(uint8_t reg)
{
    //    while ((I2C_SR2(i2c) & I2C_SR2_BUSY)) {
    //    }

    i2c_send_start(I2C_PORT);

    /* Wait for master mode selected */
    while (!((I2C_SR1(I2C_PORT) & I2C_SR1_SB)
           & (I2C_SR2(I2C_PORT) & (I2C_SR2_MSL | I2C_SR2_BUSY))));

    i2c_send_7bit_address(I2C_PORT, SLAVE_ADDRESS, I2C_WRITE);

    /* Waiting for address is transferred. */
    while (!(I2C_SR1(I2C_PORT) & I2C_SR1_ADDR));

    /* Cleaning ADDR condition sequence. */
    uint32_t reg32 = I2C_SR2(I2C_PORT);
    (void) reg32; /* unused */

    /*  Common stuff ABOVE HERE     */

    i2c_send_data(I2C_PORT, reg);
    while (!(I2C_SR1(I2C_PORT) & (I2C_SR1_BTF)));

    i2c_send_start(I2C_PORT);

    /* Wait for master mode selected */
    while (!((I2C_SR1(I2C_PORT) & I2C_SR1_SB)
           & (I2C_SR2(I2C_PORT) & (I2C_SR2_MSL | I2C_SR2_BUSY))));

    i2c_send_7bit_address(I2C_PORT, SLAVE_ADDRESS, I2C_READ);

    /* Waiting for address is transferred. */
    while (!(I2C_SR1(I2C_PORT) & I2C_SR1_ADDR));

    i2c_disable_ack(I2C_PORT);

    /* Cleaning ADDR condition sequence. */
    reg32 = I2C_SR2(I2C_PORT);
    (void) reg32; /* unused */

    i2c_send_stop(I2C_PORT);

    while (!(I2C_SR1(I2C_PORT) & I2C_SR1_RxNE));
    uint32_t result = i2c_get_data(I2C_PORT);

    i2c_enable_ack(I2C_PORT);
    I2C_SR1(I2C_PORT) &= ~I2C_SR1_AF;
    return result;
}
Ejemplo n.º 6
0
/*
 * IRQ handler for I2C master. Handles transmission/reception.
 */
void _i2c_irq_handler(i2c_dev *dev) {
    /* WTFs:
     * - Where is I2C_MSG_10BIT_ADDR handled?
     */
    i2c_msg *msg = dev->msg;

    uint8 read = msg->flags & I2C_MSG_READ;

    uint32 sr1 = dev->regs->SR1;
    uint32 sr2 = dev->regs->SR2;
    I2C_CRUMB(IRQ_ENTRY, sr1, sr2);

    /*
     * Reset timeout counter
     */
    dev->timestamp = systick_uptime();

    /*
     * Add Slave support
     */

    /* Check to see if MSL master slave bit is set */
    if ((sr2 & I2C_SR2_MSL) != I2C_SR2_MSL) { /* 0 = slave mode 1 = master */

        /* Check for address match */
        if (sr1 & I2C_SR1_ADDR) {
            /* Find out which address was matched */
            /* Check the general call address first */
            if (sr2 & I2C_SR2_GENCALL) {
                dev->i2c_slave_msg->addr = 0;
            }
            /* We matched the secondary address */
            else if (sr2 & I2C_SR2_DUALF) {
                dev->i2c_slave_msg->addr = dev->regs->OAR2 & 0xFE;
            }
            /* We matched the primary address */
            else if ((sr2 & I2C_SR2_DUALF) != I2C_SR2_DUALF) {
                dev->i2c_slave_msg->addr = dev->regs->OAR1 & 0xFE;
            }
            /* Shouldn't get here */
            else {
                dev->i2c_slave_msg->addr = -1; /* uh oh */
            }

            /* if we have buffered io */
            if ((dev->config_flags & I2C_SLAVE_USE_RX_BUFFER) ||
                (dev->config_flags & I2C_SLAVE_USE_TX_BUFFER)) {

                /* if receiving then this would be a repeated start
                 *
                 *if we have some bytes already
                 */
                if ((dev->state == I2C_STATE_SL_RX) &&
                    (dev->i2c_slave_msg->xferred > 0)  &&
                    (dev->config_flags & I2C_SLAVE_USE_RX_BUFFER)) {
                    /* Call the callback with the contents of the data */
                    if (dev->i2c_slave_recv_callback != NULL) {
                        (*(dev->i2c_slave_recv_callback))(dev->i2c_slave_msg);
                    }
                }

                /* Reset the message back to defaults.
                 * We are starting a new message
                 */
                dev->i2c_slave_msg->flags = 0;
                dev->i2c_slave_msg->length = 0;
                dev->i2c_slave_msg->xferred = 0;
                dev->msgs_left = 0;
                dev->timestamp = systick_uptime();

                /* We have been addressed with SLA+R so
                 * the master wants us to transmit
                 */
                if ((sr1 & I2C_SR1_TXE) &&
                    (dev->config_flags & I2C_SLAVE_USE_TX_BUFFER)) {
                    /* Call the transmit callback so it can populate the msg
                     * data with the bytes to go
                     */
                    if (dev->i2c_slave_transmit_callback != NULL) {
                        (*(dev->i2c_slave_transmit_callback))(dev->i2c_slave_msg);
                    }
                }
                dev->state = I2C_STATE_BUSY;
            }

            sr1 = sr2 = 0;
        }
        
         /* EV3: Master requesting data from slave. Transmit a byte*/
        if (sr1 & I2C_SR1_TXE) {
            if (dev->config_flags & I2C_SLAVE_USE_TX_BUFFER) {
                if (dev->i2c_slave_msg->xferred >= dev->i2c_slave_msg->length) {
                    /* End of the transmit buffer? If so we NACK */
                    i2c_disable_ack(dev);
                    /* We have to either issue a STOP or write something here.
                     * STOP here seems to screw up some masters,
                     * For now padding with 0
                     */
                    i2c_write(dev, 0);
                    /*i2c_stop_condition(dev); // This is causing bus lockups way more than it should !? Seems some I2C master devices freak out here*/
                }
                else
                {
                    /* NACk the last byte */
                    if (dev->i2c_slave_msg->xferred == dev->i2c_slave_msg->length-1) {
                        i2c_disable_ack(dev);
                    }
                    else {
                        i2c_enable_ack(dev);
                    }
                    i2c_write(dev, dev->i2c_slave_msg->data[dev->i2c_slave_msg->xferred++]);
                }
            }
            else
            {
                /* Call the callback to get the data we need.
                 * The callback is expected to write using i2c_write(...)
                 * If the slave is going to terminate the transfer, this function should
                 * also do a NACK on the last byte!
                 */
                if (dev->i2c_slave_transmit_callback != NULL) (*(dev->i2c_slave_transmit_callback))(dev->i2c_slave_msg);
            }

            dev->state = I2C_STATE_BUSY;
            sr1 = sr2 = 0;
        }
        
        /* EV2: Slave received data from a master. Get from DR */
        if (sr1 & I2C_SR1_RXNE) {
            if (dev->config_flags & I2C_SLAVE_USE_RX_BUFFER) {
                /* Fill the buffer with the contents of the data register */
                /* These is potential for buffer overflow here, so we should
                 * really store the size of the array. This is expensive in
                 * the ISR so left out for now. We must trust the implementor!
                 */
                dev->i2c_slave_msg->data[dev->i2c_slave_msg->xferred++] = dev->regs->DR;
                dev->i2c_slave_msg->length++;
            }
            else  {
                /* Call the callback with the contents of the data */
                dev->i2c_slave_msg->data[0] = dev->regs->DR;
                if (dev->i2c_slave_recv_callback != NULL) (*(dev->i2c_slave_recv_callback))(dev->i2c_slave_msg);
            }
            dev->state = I2C_STATE_SL_RX;
            sr1 = sr2 = 0;
        }

        /* EV4: Slave has detected a STOP condition on the bus */
        if (sr1 & I2C_SR1_STOPF) {
            dev->regs->CR1 |= I2C_CR1_PE;

            if ((dev->config_flags & I2C_SLAVE_USE_RX_BUFFER) ||
                (dev->config_flags & I2C_SLAVE_USE_TX_BUFFER)) {

                /* The callback with the data will happen on a NACK of the last data byte.
                 * This is handled in the error IRQ (AF bit)
                 */
                /* Handle the case where the master misbehaves by sending no NACK */
                if (dev->state != I2C_STATE_IDLE) {
                    if (dev->state == I2C_STATE_SL_RX) {
                        if (dev->i2c_slave_recv_callback != NULL) (*(dev->i2c_slave_recv_callback))(dev->i2c_slave_msg);
                    }
                    else {
                        if (dev->i2c_slave_transmit_callback != NULL) (*(dev->i2c_slave_transmit_callback))(dev->i2c_slave_msg);
                    }
                }
            }

            sr1 = sr2 = 0;
            dev->state = I2C_STATE_IDLE;
        }

        return;
    }
    
    /*
     * EV5: Start condition sent
     */
    if (sr1 & I2C_SR1_SB) {
        msg->xferred = 0;
        i2c_enable_irq(dev, I2C_IRQ_BUFFER);

        /*
         * Master receiver
         */
        if (read) {
            i2c_enable_ack(dev);
        }

        i2c_send_slave_addr(dev, msg->addr, read);
        sr1 = sr2 = 0;
    }

    /*
     * EV6: Slave address sent
     */
    if (sr1 & I2C_SR1_ADDR) {
        /*
         * Special case event EV6_1 for master receiver.
         * Generate NACK and restart/stop condition after ADDR
         * is cleared.
         */
        if (read) {
            if (msg->length == 1) {
                i2c_disable_ack(dev);
                if (dev->msgs_left > 1) {
                    i2c_start_condition(dev);
                    I2C_CRUMB(RX_ADDR_START, 0, 0);
                } else {
                    i2c_stop_condition(dev);
                    I2C_CRUMB(RX_ADDR_STOP, 0, 0);
                }
            }
        } else {
            /*
             * Master transmitter: write first byte to fill shift
             * register.  We should get another TXE interrupt
             * immediately to fill DR again.
             */
            if (msg->length != 1) {
                i2c_write(dev, msg->data[msg->xferred++]);
            }
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV8: Master transmitter
     * Transmit buffer empty, but we haven't finished transmitting the last
     * byte written.
     */
    if ((sr1 & I2C_SR1_TXE) && !(sr1 & I2C_SR1_BTF)) {
        I2C_CRUMB(TXE_ONLY, 0, 0);
        if (dev->msgs_left) {
            i2c_write(dev, msg->data[msg->xferred++]);
            if (msg->xferred == msg->length) {
                /*
                 * End of this message. Turn off TXE/RXNE and wait for
                 * BTF to send repeated start or stop condition.
                 */
                i2c_disable_irq(dev, I2C_IRQ_BUFFER);
                dev->msgs_left--;
            }
        } else {
            /*
             * This should be impossible...
             */
            ASSERT(0);
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV8_2: Master transmitter
     * Last byte sent, program repeated start/stop
     */
    if ((sr1 & I2C_SR1_TXE) && (sr1 & I2C_SR1_BTF)) {
        I2C_CRUMB(TXE_BTF, 0, 0);
        if (dev->msgs_left) {
            I2C_CRUMB(TEST, 0, 0);
            /*
             * Repeated start insanity: We can't disable ITEVTEN or else SB
             * won't interrupt, but if we don't disable ITEVTEN, BTF will
             * continually interrupt us. What the f**k ST?
             */
            i2c_start_condition(dev);
            while (!(dev->regs->SR1 & I2C_SR1_SB))
                ;
            dev->msg++;
        } else {
            i2c_stop_condition(dev);

            /*
             * Turn off event interrupts to keep BTF from firing until
             * the end of the stop condition. Why on earth they didn't
             * have a start/stop condition request clear BTF is beyond
             * me.
             */
            i2c_disable_irq(dev, I2C_IRQ_EVENT);
            I2C_CRUMB(STOP_SENT, 0, 0);
            dev->state = I2C_STATE_XFER_DONE;
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV7: Master Receiver
     */
    if (sr1 & I2C_SR1_RXNE) {
        I2C_CRUMB(RXNE_ONLY, 0, 0);
        msg->data[msg->xferred++] = dev->regs->DR;

        /*
         * EV7_1: Second to last byte in the reception? Set NACK and generate
         * stop/restart condition in time for the last byte. We'll get one more
         * RXNE interrupt before shutting things down.
         */
        if (msg->xferred == (msg->length - 1)) {
            i2c_disable_ack(dev);
            if (dev->msgs_left > 2) {
                i2c_start_condition(dev);
                I2C_CRUMB(RXNE_START_SENT, 0, 0);
            } else {
                i2c_stop_condition(dev);
                I2C_CRUMB(RXNE_STOP_SENT, 0, 0);
            }
        } else if (msg->xferred == msg->length) {
            dev->msgs_left--;
            if (dev->msgs_left == 0) {
                /*
                 * We're done.
                 */
                I2C_CRUMB(RXNE_DONE, 0, 0);
                dev->state = I2C_STATE_XFER_DONE;
            } else {
                dev->msg++;
            }
        }
    }

}
Ejemplo n.º 7
0
// Doc ID 13902 Rev 11 p 712/1072
// Transfer Sequence Diagram for Master Receiver for N>2
static inline enum STMI2CSubTransactionStatus stmi2c_readmany(uint32_t i2c, struct i2c_periph *periph, struct i2c_transaction *trans)
{
  uint16_t SR1 = I2C_SR1(i2c);

  // Start Condition Was Just Generated
  if (BIT_X_IS_SET_IN_REG( I2C_SR1_SB, SR1 ) )
  {
    i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);
    // The first data byte will be acked in read many so the slave knows it should send more
    i2c_nack_current(i2c);
    i2c_enable_ack(i2c);
    // Clear the SB flag
    i2c_send_data(i2c, trans->slave_addr | 0x01);

    // Document the current Status
    periph->status = I2CAddrRdSent;
  }
  // Address Was Sent
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_ADDR, SR1) )
  {
    periph->idx_buf = 0;

    // Enable RXNE: receive an interrupt any time a byte is available
    // only enable if MORE than 3 bytes need to be read
    if (periph->idx_buf < (trans->len_r - 3))
    {
      i2c_enable_interrupt(i2c, I2C_CR2_ITBUFEN);
    }

    // ACK is still on to get more DATA
    // Read SR2 to clear the ADDR (next byte will start arriving)
    uint16_t SR2 __attribute__ ((unused)) = I2C_SR2(i2c);

    // Document the current Status
    periph->status = I2CReadingByte;
  }
  // one or more bytes are available AND we were interested in Buffer interrupts
  else if ( (BIT_X_IS_SET_IN_REG(I2C_SR1_RxNE, SR1) ) && (BIT_X_IS_SET_IN_REG(I2C_CR2_ITBUFEN, I2C_CR2(i2c)))  )
  {
    // read byte until 3 bytes remain to be read (e.g. len_r = 6, -> idx=3 means idx 3,4,5 = 3 remain to be read
    if (periph->idx_buf < (trans->len_r - 3))
    {
      trans->buf[periph->idx_buf] = I2C_DR(i2c);
      periph->idx_buf ++;
    }
    // from : 3bytes -> last byte: do nothing
    //
    // finally: this was the last byte
    else if (periph->idx_buf >= (trans->len_r - 1))
    {
      i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);

      // Last Value
      trans->buf[periph->idx_buf] = i2c_get_data(i2c);
      periph->idx_buf ++;

      // We got all the results
      trans->status = I2CTransSuccess;

      return STMI2C_SubTra_Ready_StopRequested;
    }

    // Check for end of transaction: start waiting for BTF instead of RXNE
    if (periph->idx_buf < (trans->len_r - 3))
    {
      i2c_enable_interrupt(i2c, I2C_CR2_ITBUFEN);
    }
    else // idx >= len-3: there are 3 bytes to be read
    {
      // We want to halt I2C to have sufficient time to clear ACK, so:
      // Stop listening to RXNE as it will be triggered infinitely since we did not empty the buffer
      // on the next (second in buffer) received byte BTF will be set (buffer full and I2C halted)
      i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);
    }
  }
  // Buffer is full while this was not a RXNE interrupt
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_BTF, SR1) )
  {
    // Now the shift register and data register contain data(n-2) and data(n-1)
    // And I2C is halted so we have time

    // --- Make absolutely sure the next 2 I2C actions are performed with no delay
    __I2C_REG_CRITICAL_ZONE_START;

    // First we clear the ACK while the SCL is held low by BTF
    i2c_disable_ack(i2c);

    // Now that ACK is cleared we read one byte: instantly the last byte is being clocked in...
    trans->buf[periph->idx_buf] = i2c_get_data(i2c);
    periph->idx_buf ++;

    // Now the last byte is being clocked. Stop in MUST be set BEFORE the transfer of the last byte is complete
    PPRZ_I2C_SEND_STOP(i2c);

    __I2C_REG_CRITICAL_ZONE_STOP;


    // --- end of critical zone -----------

    // Document the current Status
    periph->status = I2CStopRequested;

    // read the byte2 we had in the buffer (BTF means 2 bytes available)
    trans->buf[periph->idx_buf] = i2c_get_data(i2c);
    periph->idx_buf ++;

    // Ask for an interrupt to read the last byte (which is normally still busy now)
    // The last byte will be received with RXNE
    i2c_enable_interrupt(i2c, I2C_CR2_ITBUFEN);
  }
  else // Event Logic Error
  {
    return STMI2C_SubTra_Error;
  }

  return STMI2C_SubTra_Busy;
}
Ejemplo n.º 8
0
// Doc ID 13902 Rev 11 p 713/1072
// Transfer Sequence Diagram for Master Receiver for N=2
static inline enum STMI2CSubTransactionStatus stmi2c_read2(uint32_t i2c, struct i2c_periph *periph, struct i2c_transaction *trans)
{
  uint16_t SR1 = I2C_SR1(i2c);

  // Start Condition Was Just Generated
  if (BIT_X_IS_SET_IN_REG( I2C_SR1_SB, SR1 ) )
  {
    // according to the datasheet: instantly shedule a NAK on the second received byte:
    i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);
    i2c_enable_ack(i2c);
    i2c_nack_next(i2c);
    i2c_send_data(i2c, trans->slave_addr | 0x01);

    // Document the current Status
    periph->status = I2CAddrRdSent;
  }
  // Address Was Sent
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_ADDR, SR1) )
  {
    // --- make absolutely sure this command is not delayed too much after the previous:
    // --- the NAK bits must be set before the first byte arrived: allow other interrupts here
    __I2C_REG_CRITICAL_ZONE_START;

    //       if transfer of DR was finished already then we will get too many bytes
    // BEFORE clearing ACK, read SR2 to clear the ADDR (next byte will start arriving)
    // clearing ACK after the byte transfer has already started will NACK the next (2nd)
    uint16_t SR2 __attribute__ ((unused)) = I2C_SR2(i2c);

    // NOT First Clear the ACK bit but only AFTER clearing ADDR
    i2c_disable_ack(i2c);

    // Disable the RXNE and wait for BTF
    i2c_disable_interrupt(i2c, I2C_CR2_ITBUFEN);

    __I2C_REG_CRITICAL_ZONE_STOP;
    // --- end of critical zone -----------

    // We do not set the RxE but wait for both bytes to arrive using BTF

    // Document the current Status
    periph->status = I2CReadingByte;
  }
  // Receive buffer if full, master is halted: BTF
  else if (BIT_X_IS_SET_IN_REG(I2C_SR1_BTF, SR1) )
  {
    // Stop condition MUST be set BEFORE reading the DR
    // otherwise since there is new buffer space a new byte will be read
    PPRZ_I2C_SEND_STOP(i2c);

    // Document the current Status
    periph->status = I2CStopRequested;

    trans->buf[0] = I2C_DR(i2c);
    trans->buf[1] = I2C_DR(i2c);

    // We got all the results
    trans->status = I2CTransSuccess;

    return STMI2C_SubTra_Ready_StopRequested;
  }
  else // Event Logic Error
  {
    return STMI2C_SubTra_Error;
  }

  return STMI2C_SubTra_Busy;
}
Ejemplo n.º 9
0
/**
 * @brief IRQ handler for I2C master. Handles transmission/reception.
 * @param dev I2C device
 */
static void i2c_irq_handler(i2c_dev *dev) {
    i2c_msg *msg = dev->msg;

    uint8 read = msg->flags & I2C_MSG_READ;

    uint32 sr1 = dev->regs->SR1;
    uint32 sr2 = dev->regs->SR2;
    I2C_CRUMB(IRQ_ENTRY, sr1, sr2);

    /*
     * Reset timeout counter
     */
    dev->timestamp = systick_uptime();

    /*
     * EV5: Start condition sent
     */
    if (sr1 & I2C_SR1_SB) {
        msg->xferred = 0;
        i2c_enable_irq(dev, I2C_IRQ_BUFFER);

        /*
         * Master receiver
         */
        if (read) {
            i2c_enable_ack(dev);
        }

        i2c_send_slave_addr(dev, msg->addr, read);
        sr1 = sr2 = 0;
    }

    /*
     * EV6: Slave address sent
     */
    if (sr1 & I2C_SR1_ADDR) {
        /*
         * Special case event EV6_1 for master receiver.
         * Generate NACK and restart/stop condition after ADDR
         * is cleared.
         */
        if (read) {
            if (msg->length == 1) {
                i2c_disable_ack(dev);
                if (dev->msgs_left > 1) {
                    i2c_start_condition(dev);
                    I2C_CRUMB(RX_ADDR_START, 0, 0);
                } else {
                    i2c_stop_condition(dev);
                    I2C_CRUMB(RX_ADDR_STOP, 0, 0);
                }
            }
        } else {
            /*
             * Master transmitter: write first byte to fill shift
             * register.  We should get another TXE interrupt
             * immediately to fill DR again.
             */
            if (msg->length != 1) {
                i2c_write(dev, msg->data[msg->xferred++]);
            }
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV8: Master transmitter
     * Transmit buffer empty, but we haven't finished transmitting the last
     * byte written.
     */
    if ((sr1 & I2C_SR1_TXE) && !(sr1 & I2C_SR1_BTF)) {
        I2C_CRUMB(TXE_ONLY, 0, 0);
        if (dev->msgs_left) {
            i2c_write(dev, msg->data[msg->xferred++]);
            if (msg->xferred == msg->length) {
                /*
                 * End of this message. Turn off TXE/RXNE and wait for
                 * BTF to send repeated start or stop condition.
                 */
                i2c_disable_irq(dev, I2C_IRQ_BUFFER);
                dev->msgs_left--;
            }
        } else {
            /*
             * This should be impossible...
             */
            throb();
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV8_2: Master transmitter
     * Last byte sent, program repeated start/stop
     */
    if ((sr1 & I2C_SR1_TXE) && (sr1 & I2C_SR1_BTF)) {
        I2C_CRUMB(TXE_BTF, 0, 0);
        if (dev->msgs_left) {
            I2C_CRUMB(TEST, 0, 0);
            /*
             * Repeated start insanity: We can't disable ITEVTEN or else SB
             * won't interrupt, but if we don't disable ITEVTEN, BTF will
             * continually interrupt us. What the f**k ST?
             */
            i2c_start_condition(dev);
            while (!(dev->regs->SR1 & I2C_SR1_SB))
                ;
            dev->msg++;
        } else {
            i2c_stop_condition(dev);

            /*
             * Turn off event interrupts to keep BTF from firing until
             * the end of the stop condition. Why on earth they didn't
             * have a start/stop condition request clear BTF is beyond
             * me.
             */
            i2c_disable_irq(dev, I2C_IRQ_EVENT);
            I2C_CRUMB(STOP_SENT, 0, 0);
            dev->state = I2C_STATE_XFER_DONE;
        }
        sr1 = sr2 = 0;
    }

    /*
     * EV7: Master Receiver
     */
    if (sr1 & I2C_SR1_RXNE) {
        I2C_CRUMB(RXNE_ONLY, 0, 0);
        msg->data[msg->xferred++] = dev->regs->DR;

        /*
         * EV7_1: Second to last byte in the reception? Set NACK and generate
         * stop/restart condition in time for the last byte. We'll get one more
         * RXNE interrupt before shutting things down.
         */
        if (msg->xferred == (msg->length - 1)) {
            i2c_disable_ack(dev);
            if (dev->msgs_left > 2) {
                i2c_start_condition(dev);
                I2C_CRUMB(RXNE_START_SENT, 0, 0);
            } else {
                i2c_stop_condition(dev);
                I2C_CRUMB(RXNE_STOP_SENT, 0, 0);
            }
        } else if (msg->xferred == msg->length) {
            dev->msgs_left--;
            if (dev->msgs_left == 0) {
                /*
                 * We're done.
                 */
                I2C_CRUMB(RXNE_DONE, 0, 0);
                dev->state = I2C_STATE_XFER_DONE;
            } else {
                dev->msg++;
            }
        }
    }
}
Ejemplo n.º 10
0
static void setup_i2c_port(enum I2C_FREQ I2C_speed)
{
	// Disable I2C if it happens to be enabled
	i2c_peripheral_disable(I2C_PORT);
	dma_channel_reset(I2C_TX_DMA, I2C_TX_DMA_CHANNEL);
	i2c_disable_interrupt(I2C_PORT, (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN));
	DISABLE_I2C_INTERRUPT();
	reset_i2c_pins();

	// set: Source, Destination, and Amount (DMA channel must be disabled)
	dma_set_peripheral_address(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, (uint32_t)&I2C_DR(I2C_PORT));
	dma_set_memory_address(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, 0);
	dma_set_number_of_data(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, 0);
	// set the DMA Configuration (DMA_CCRx)
	//			 (BIT 14) mem2mem_mode disabled
	dma_set_priority(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_PL_HIGH); // (BIT 12:13)
	dma_set_memory_size(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_MSIZE_8BIT); // (BIT 10:11)
	dma_set_peripheral_size(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_PSIZE_8BIT); // (BIT 8:9)
	dma_enable_memory_increment_mode(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 7)
	dma_disable_peripheral_increment_mode(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 6)
	//			 (BIT 5) Circular mode is disabled
	dma_set_read_from_memory(I2C_TX_DMA, I2C_TX_DMA_CHANNEL);	// (BIT 4)
	dma_enable_transfer_error_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 3)
	dma_disable_half_transfer_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 2)
	dma_enable_transfer_complete_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 1)

	// This is the slave address when not transmitting data
	i2c_set_own_7bit_slave_address(I2C_PORT, 0x32);
	// do not respond to the specified slave address
	i2c_disable_ack(I2C_PORT);
	// Use DMA to send I2C data
	i2c_enable_dma(I2C_PORT);
	// set which interrupts I2C uses
	i2c_enable_interrupt(I2C_PORT, (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN));
	// APB1 is running at 36MHz = T(PCLK1) = 1/36000000 sec.
	i2c_set_clock_frequency(I2C_PORT, I2C_CR2_FREQ_36MHZ);
	// Set up the hardware for the particular speed
	switch (I2C_speed) {
		// Values found on Internet for the I2C standard
		//   STANDARD : SCL max rise time = 1000ns = 1000/1000000000 sec
		//       FAST : SCL max rise time =  300ns =  300/1000000000 sec
		// 
		// DATASHEET Function:
		//   TRISE = (T(MAX_SCL_RISE) / T(PCLK1)) + 1
		// 
		// DATASHEET Functions:
		//   STANDARD :      
		//     T(high) =      CCR * T(PCLK1)
		//     T(low)  =      CCR * T(PCLK1)
		//   FAST (DUTY=I2C_CCR_DUTY_DIV2)
		//     T(high) =      CCR * T(PCLK1)
		//     T(low)  =  2 * CCR * T(PCLK1)
		//   FAST (DUTY=I2C_CCR_DUTY_16_DIV_9)   [To reach 400KHz]
		//     T(high) =  9 * CCR * T(PCLK1)
		//     T(low)  = 16 * CCR * T(PCLK1)
		// 
		// I2C PERIOD:
		//   STANDARD
		//     PERIOD = T(high) + T(low) = (2 * CCR * T(PCLK1))
		//   FAST (DUTY=I2C_CCR_DUTY_DIV2)
		//     PERIOD = T(high) + T(low) = (3 * CCR * T(PCLK1))
		//   FAST (DUTY=I2C_CCR_DUTY_16_DIV_9)
		//     PERIOD = T(high) + T(low) = (25 * CCR * T(PCLK1))
		case I2C_400KHz:
			// I2C PERIOD: 400KHz = 400000Hz = 1/400000 sec.
			i2c_set_fast_mode(I2C_PORT);
			// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
			i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_16_DIV_9);
			// CCR = PERIOD / (25 * T(PCLK1))
			// CCR = (1/400000) / (25/36000000) = 18/5 = 3.6
			// CCR = 4 => I2C PERIOD = 360kHz
			// CCR = 3 => I2C PERIOD = 480kHz
			i2c_set_ccr(I2C_PORT, 4);	// Only fast mode can have a value less than 0x04
			// TRISE = ( (300/1000000000) / (1/36000000) ) + 1 = 59/5 = 11.8
			// TRISE = 12 => SCL max rise time ~= 305.555ns
			// TRISE = 11 => SCL max rise time ~= 277.777ns
			i2c_set_trise(I2C_PORT, 11);
			break;
		case I2C_100KHz:
			// I2C PERIOD: 100KHz = 100000Hz = 1/100000 sec.
			i2c_set_standard_mode(I2C_PORT);
			// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
			i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_DIV2);
			// CCR = PERIOD / (2 * T(PCLK1))
			// CCR = (1/100000) / (2/36000000) = 180
			i2c_set_ccr(I2C_PORT, 180);
			// TRISE = ( (1000/1000000000) / (1/36000000) ) + 1 = 37
			i2c_set_trise(I2C_PORT, 37);
			break;
		case I2C_53KHz:
			// ~= 52.91kHz is the slowest I could get to work
			// CCR value of 341 works but not 342 or higher
		case I2C_50KHz:
		default:
			// I2C PERIOD: 50KHz = 50000Hz = 1/50000 sec.
			i2c_set_standard_mode(I2C_PORT);
			// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
			i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_DIV2);
			// CCR = PERIOD / (2 * T(PCLK1))
			// CCR = (1/50000) / (2/36000000) = 360
			//   (341 works but not 342 or higher)
			i2c_set_ccr(I2C_PORT, 341);
			// TRISE = ( (1000/1000000000) / (1/36000000) ) + 1 = 37
			i2c_set_trise(I2C_PORT, 37);
			break;
	}
	i2c_peripheral_enable(I2C_PORT);

	// set the priorities for the interrupts
	nvic_set_priority(I2C_EV_IRQ, IRQ_PRI_I2C);
	nvic_set_priority(I2C_ER_IRQ, IRQ_PRI_ER_I2C);
	nvic_set_priority(I2C_DMA_IRQ, IRQ_PRI_DMA_I2C);
}