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/* Copyright (C) 2019 Elia Ritterbusch
+
* This program is free software : you can redistribute it and / or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation , either version 3 of the License , or
* ( at your option ) any later version .
*
* This program is distributed in the hope that it will be useful ,
* but WITHOUT ANY WARRANTY ; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
* GNU General Public License for more details .
*
* You should have received a copy of the GNU General Public License
* along with this program . If not , see < https : //www.gnu.org/licenses/>.
*/
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/* Library made by: g4lvanix
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* GitHub repository : https : //github.com/g4lvanix/I2C-master-lib
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*/
# include <avr/io.h>
# include <util/twi.h>
# include "i2c_master.h"
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# include "timer.h"
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# include "wait.h"
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# ifndef F_SCL
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# define F_SCL 400000UL // SCL frequency
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# endif
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# ifndef I2C_START_RETRY_COUNT
# define I2C_START_RETRY_COUNT 20
# endif // I2C_START_RETRY_COUNT
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# define I2C_ACTION_READ 0x01
# define I2C_ACTION_WRITE 0x00
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# define TWBR_val (((F_CPU / F_SCL) - 16) / 2)
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# define MAX(X, Y) ((X) > (Y) ? (X) : (Y))
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void i2c_init ( void ) {
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TWSR = 0 ; /* no prescaler */
TWBR = ( uint8_t ) TWBR_val ;
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# ifdef __AVR_ATmega32A__
// set pull-up resistors on I2C bus pins
PORTC | = 0 b11 ;
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// enable TWI (two-wire interface)
TWCR | = ( 1 < < TWEN ) ;
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// enable TWI interrupt and slave address ACK
TWCR | = ( 1 < < TWIE ) ;
TWCR | = ( 1 < < TWEA ) ;
# endif
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}
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static i2c_status_t i2c_start_impl ( uint8_t address , uint16_t timeout ) {
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// reset TWI control register
TWCR = 0 ;
// transmit START condition
TWCR = ( 1 < < TWINT ) | ( 1 < < TWSTA ) | ( 1 < < TWEN ) ;
uint16_t timeout_timer = timer_read ( ) ;
while ( ! ( TWCR & ( 1 < < TWINT ) ) ) {
if ( ( timeout ! = I2C_TIMEOUT_INFINITE ) & & ( ( timer_read ( ) - timeout_timer ) > = timeout ) ) {
return I2C_STATUS_TIMEOUT ;
}
}
// check if the start condition was successfully transmitted
if ( ( ( TW_STATUS & 0xF8 ) ! = TW_START ) & & ( ( TW_STATUS & 0xF8 ) ! = TW_REP_START ) ) {
return I2C_STATUS_ERROR ;
}
// load slave address into data register
TWDR = address ;
// start transmission of address
TWCR = ( 1 < < TWINT ) | ( 1 < < TWEN ) ;
timeout_timer = timer_read ( ) ;
while ( ! ( TWCR & ( 1 < < TWINT ) ) ) {
if ( ( timeout ! = I2C_TIMEOUT_INFINITE ) & & ( ( timer_read ( ) - timeout_timer ) > = timeout ) ) {
return I2C_STATUS_TIMEOUT ;
}
}
// check if the device has acknowledged the READ / WRITE mode
uint8_t twst = TW_STATUS & 0xF8 ;
if ( ( twst ! = TW_MT_SLA_ACK ) & & ( twst ! = TW_MR_SLA_ACK ) ) {
return I2C_STATUS_ERROR ;
}
return I2C_STATUS_SUCCESS ;
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}
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i2c_status_t i2c_start ( uint8_t address , uint16_t timeout ) {
// Retry i2c_start_impl a bunch times in case the remote side has interrupts disabled.
uint16_t timeout_timer = timer_read ( ) ;
uint16_t time_slice = MAX ( 1 , ( timeout = = ( I2C_TIMEOUT_INFINITE ) ) ? 5 : ( timeout / ( I2C_START_RETRY_COUNT ) ) ) ; // if it's infinite, wait 1ms between attempts, otherwise split up the entire timeout into the number of retries
i2c_status_t status ;
do {
status = i2c_start_impl ( address , time_slice ) ;
} while ( ( status < 0 ) & & ( ( timeout = = I2C_TIMEOUT_INFINITE ) | | ( timer_elapsed ( timeout_timer ) < timeout ) ) ) ;
return status ;
}
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i2c_status_t i2c_write ( uint8_t data , uint16_t timeout ) {
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// load data into data register
TWDR = data ;
// start transmission of data
TWCR = ( 1 < < TWINT ) | ( 1 < < TWEN ) ;
uint16_t timeout_timer = timer_read ( ) ;
while ( ! ( TWCR & ( 1 < < TWINT ) ) ) {
if ( ( timeout ! = I2C_TIMEOUT_INFINITE ) & & ( ( timer_read ( ) - timeout_timer ) > = timeout ) ) {
return I2C_STATUS_TIMEOUT ;
}
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}
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if ( ( TW_STATUS & 0xF8 ) ! = TW_MT_DATA_ACK ) {
return I2C_STATUS_ERROR ;
}
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return I2C_STATUS_SUCCESS ;
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}
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int16_t i2c_read_ack ( uint16_t timeout ) {
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// start TWI module and acknowledge data after reception
TWCR = ( 1 < < TWINT ) | ( 1 < < TWEN ) | ( 1 < < TWEA ) ;
uint16_t timeout_timer = timer_read ( ) ;
while ( ! ( TWCR & ( 1 < < TWINT ) ) ) {
if ( ( timeout ! = I2C_TIMEOUT_INFINITE ) & & ( ( timer_read ( ) - timeout_timer ) > = timeout ) ) {
return I2C_STATUS_TIMEOUT ;
}
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}
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// return received data from TWDR
return TWDR ;
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}
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int16_t i2c_read_nack ( uint16_t timeout ) {
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// start receiving without acknowledging reception
TWCR = ( 1 < < TWINT ) | ( 1 < < TWEN ) ;
uint16_t timeout_timer = timer_read ( ) ;
while ( ! ( TWCR & ( 1 < < TWINT ) ) ) {
if ( ( timeout ! = I2C_TIMEOUT_INFINITE ) & & ( ( timer_read ( ) - timeout_timer ) > = timeout ) ) {
return I2C_STATUS_TIMEOUT ;
}
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}
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// return received data from TWDR
return TWDR ;
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}
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i2c_status_t i2c_transmit ( uint8_t address , const uint8_t * data , uint16_t length , uint16_t timeout ) {
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i2c_status_t status = i2c_start ( address | I2C_ACTION_WRITE , timeout ) ;
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for ( uint16_t i = 0 ; i < length & & status > = 0 ; i + + ) {
status = i2c_write ( data [ i ] , timeout ) ;
}
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i2c_stop ( ) ;
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return status ;
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}
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i2c_status_t i2c_receive ( uint8_t address , uint8_t * data , uint16_t length , uint16_t timeout ) {
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i2c_status_t status = i2c_start ( address | I2C_ACTION_READ , timeout ) ;
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for ( uint16_t i = 0 ; i < ( length - 1 ) & & status > = 0 ; i + + ) {
status = i2c_read_ack ( timeout ) ;
if ( status > = 0 ) {
data [ i ] = status ;
}
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}
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if ( status > = 0 ) {
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status = i2c_read_nack ( timeout ) ;
if ( status > = 0 ) {
data [ ( length - 1 ) ] = status ;
}
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}
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i2c_stop ( ) ;
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return ( status < 0 ) ? status : I2C_STATUS_SUCCESS ;
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}
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i2c_status_t i2c_writeReg ( uint8_t devaddr , uint8_t regaddr , const uint8_t * data , uint16_t length , uint16_t timeout ) {
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i2c_status_t status = i2c_start ( devaddr | 0x00 , timeout ) ;
if ( status > = 0 ) {
status = i2c_write ( regaddr , timeout ) ;
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for ( uint16_t i = 0 ; i < length & & status > = 0 ; i + + ) {
status = i2c_write ( data [ i ] , timeout ) ;
}
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}
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i2c_stop ( ) ;
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return status ;
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}
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i2c_status_t i2c_writeReg16 ( uint8_t devaddr , uint16_t regaddr , const uint8_t * data , uint16_t length , uint16_t timeout ) {
i2c_status_t status = i2c_start ( devaddr | 0x00 , timeout ) ;
if ( status > = 0 ) {
status = i2c_write ( regaddr > > 8 , timeout ) ;
if ( status > = 0 ) {
status = i2c_write ( regaddr & 0xFF , timeout ) ;
for ( uint16_t i = 0 ; i < length & & status > = 0 ; i + + ) {
status = i2c_write ( data [ i ] , timeout ) ;
}
}
}
i2c_stop ( ) ;
return status ;
}
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i2c_status_t i2c_readReg ( uint8_t devaddr , uint8_t regaddr , uint8_t * data , uint16_t length , uint16_t timeout ) {
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i2c_status_t status = i2c_start ( devaddr , timeout ) ;
if ( status < 0 ) {
goto error ;
}
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status = i2c_write ( regaddr , timeout ) ;
if ( status < 0 ) {
goto error ;
}
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status = i2c_start ( devaddr | 0x01 , timeout ) ;
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for ( uint16_t i = 0 ; i < ( length - 1 ) & & status > = 0 ; i + + ) {
status = i2c_read_ack ( timeout ) ;
if ( status > = 0 ) {
data [ i ] = status ;
}
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}
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if ( status > = 0 ) {
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status = i2c_read_nack ( timeout ) ;
if ( status > = 0 ) {
data [ ( length - 1 ) ] = status ;
}
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}
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error :
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i2c_stop ( ) ;
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return ( status < 0 ) ? status : I2C_STATUS_SUCCESS ;
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}
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i2c_status_t i2c_readReg16 ( uint8_t devaddr , uint16_t regaddr , uint8_t * data , uint16_t length , uint16_t timeout ) {
i2c_status_t status = i2c_start ( devaddr , timeout ) ;
if ( status < 0 ) {
goto error ;
}
status = i2c_write ( regaddr > > 8 , timeout ) ;
if ( status < 0 ) {
goto error ;
}
status = i2c_write ( regaddr & 0xFF , timeout ) ;
if ( status < 0 ) {
goto error ;
}
status = i2c_start ( devaddr | 0x01 , timeout ) ;
for ( uint16_t i = 0 ; i < ( length - 1 ) & & status > = 0 ; i + + ) {
status = i2c_read_ack ( timeout ) ;
if ( status > = 0 ) {
data [ i ] = status ;
}
}
if ( status > = 0 ) {
status = i2c_read_nack ( timeout ) ;
if ( status > = 0 ) {
data [ ( length - 1 ) ] = status ;
}
}
error :
i2c_stop ( ) ;
return ( status < 0 ) ? status : I2C_STATUS_SUCCESS ;
}
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void i2c_stop ( void ) {
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// transmit STOP condition
TWCR = ( 1 < < TWINT ) | ( 1 < < TWEN ) | ( 1 < < TWSTO ) ;
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}