231 lines
4.9 KiB
C
231 lines
4.9 KiB
C
//swi2c.c
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#include "swi2c.h"
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#include <avr/io.h>
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#include <util/delay.h>
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#include <avr/pgmspace.h>
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#include "stdbool.h"
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#include "Configuration_var.h"
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#include "pins.h"
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#include "fastio.h"
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#ifdef SWI2C_SCL
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#define SWI2C_RMSK 0x01 //read mask (bit0 = 1)
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#define SWI2C_WMSK 0x00 //write mask (bit0 = 0)
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#define SWI2C_ASHF 0x01 //address shift (<< 1)
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#define SWI2C_DMSK 0x7f //device address mask
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static void __delay(void);
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static void swi2c_start(void);
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static void swi2c_stop(void);
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// static void swi2c_ack(void);
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static void swi2c_nack(void);
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static uint8_t swi2c_wait_ack();
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static uint8_t swi2c_read(void);
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static void swi2c_write(uint8_t data);
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void swi2c_init(void)
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{
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SET_INPUT(SWI2C_SDA);
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WRITE(SWI2C_SDA, 1); //SDA must be input with pullups while we are not sure if the slave is outputing or not
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WRITE(SWI2C_SCL, 0);
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SET_OUTPUT(SWI2C_SCL); //SCL can be an output at all times. The bus is not in a multi-master configuration.
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for (uint8_t i = 0; i < 100; i++) //wait. Not sure what for, but wait anyway.
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__delay();
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for (uint8_t i = 0; i < 10; i++) { //send nack 10 times. This makes sure that the slave gets a nack regardless of it's state when we init the bus.
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swi2c_nack();
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}
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swi2c_stop(); //"release" the bus by sending a stop condition.
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SET_OUTPUT(SWI2C_SDA); //finally make the SDA line an output since the bus is idle for sure.
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}
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void swi2c_disable(void)
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{
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SET_INPUT(SWI2C_SDA);
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WRITE(SWI2C_SDA, 0);
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SET_INPUT(SWI2C_SCL);
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WRITE(SWI2C_SCL, 0);
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}
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static void __delay(void)
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{
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_delay_us(1.5);
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}
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static void swi2c_start(void)
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{
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WRITE(SWI2C_SDA, 0);
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__delay();
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WRITE(SWI2C_SCL, 0);
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__delay();
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}
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static void swi2c_stop(void)
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{
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WRITE(SWI2C_SCL, 1);
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__delay();
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WRITE(SWI2C_SDA, 1);
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__delay();
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}
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/*
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static void swi2c_ack(void)
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{
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WRITE(SWI2C_SDA, 0);
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__delay();
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WRITE(SWI2C_SCL, 1);
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__delay();
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WRITE(SWI2C_SCL, 0);
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__delay();
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}
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*/
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static void swi2c_nack(void)
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{
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WRITE(SWI2C_SDA, 1);
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__delay();
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WRITE(SWI2C_SCL, 1);
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__delay();
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WRITE(SWI2C_SCL, 0);
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__delay();
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}
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static uint8_t swi2c_wait_ack()
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{
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SET_INPUT(SWI2C_SDA);
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__delay();
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// WRITE(SWI2C_SDA, 1);
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__delay();
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WRITE(SWI2C_SCL, 1);
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// __delay();
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uint8_t ack = 0;
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uint16_t ackto = SWI2C_TMO;
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while (!(ack = (!READ(SWI2C_SDA))) && ackto--) __delay();
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WRITE(SWI2C_SCL, 0);
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__delay();
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SET_OUTPUT(SWI2C_SDA);
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__delay();
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WRITE(SWI2C_SDA, 0);
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__delay();
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return ack;
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}
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static uint8_t swi2c_read(void)
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{
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WRITE(SWI2C_SDA, 1);
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__delay();
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SET_INPUT(SWI2C_SDA);
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uint8_t data = 0;
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for (uint8_t bit = 8; bit-- > 0;)
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{
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WRITE(SWI2C_SCL, 1);
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__delay();
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data |= (READ(SWI2C_SDA)) << bit;
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WRITE(SWI2C_SCL, 0);
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__delay();
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}
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SET_OUTPUT(SWI2C_SDA);
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return data;
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}
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static void swi2c_write(uint8_t data)
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{
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for (uint8_t bit = 8; bit-- > 0;)
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{
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WRITE(SWI2C_SDA, data & _BV(bit));
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__delay();
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WRITE(SWI2C_SCL, 1);
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__delay();
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WRITE(SWI2C_SCL, 0);
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__delay();
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}
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}
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uint8_t swi2c_check(uint8_t dev_addr)
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{
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swi2c_start();
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swi2c_write((dev_addr & SWI2C_DMSK) << SWI2C_ASHF);
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if (!swi2c_wait_ack()) { swi2c_stop(); return 1; }
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swi2c_stop();
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return 0;
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}
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#ifdef SWI2C_A8 //8bit address
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uint8_t swi2c_readByte_A8(uint8_t dev_addr, uint8_t addr, uint8_t* pbyte)
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{
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swi2c_start();
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swi2c_write(SWI2C_WMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) { swi2c_stop(); return 0; }
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swi2c_write(addr & 0xff);
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if (!swi2c_wait_ack()) return 0;
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swi2c_stop();
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swi2c_start();
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swi2c_write(SWI2C_RMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) return 0;
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uint8_t byte = swi2c_read();
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swi2c_stop();
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if (pbyte) *pbyte = byte;
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return 1;
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}
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uint8_t swi2c_writeByte_A8(uint8_t dev_addr, uint8_t addr, uint8_t* pbyte)
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{
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swi2c_start();
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swi2c_write(SWI2C_WMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) { swi2c_stop(); return 0; }
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swi2c_write(addr & 0xff);
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if (!swi2c_wait_ack()) return 0;
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swi2c_write(*pbyte);
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if (!swi2c_wait_ack()) return 0;
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swi2c_stop();
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return 1;
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}
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#endif //SWI2C_A8
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#ifdef SWI2C_A16 //16bit address
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uint8_t swi2c_readByte_A16(uint8_t dev_addr, unsigned short addr, uint8_t* pbyte)
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{
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swi2c_start();
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swi2c_write(SWI2C_WMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) { swi2c_stop(); return 0; }
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swi2c_write(addr >> 8);
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if (!swi2c_wait_ack()) return 0;
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swi2c_write(addr & 0xff);
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if (!swi2c_wait_ack()) return 0;
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swi2c_stop();
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swi2c_start();
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swi2c_write(SWI2C_RMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) return 0;
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uint8_t byte = swi2c_read();
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swi2c_stop();
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if (pbyte) *pbyte = byte;
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return 1;
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}
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uint8_t swi2c_writeByte_A16(uint8_t dev_addr, unsigned short addr, uint8_t* pbyte)
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{
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swi2c_start();
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swi2c_write(SWI2C_WMSK | ((dev_addr & SWI2C_DMSK) << SWI2C_ASHF));
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if (!swi2c_wait_ack()) { swi2c_stop(); return 0; }
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swi2c_write(addr >> 8);
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if (!swi2c_wait_ack()) return 0;
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swi2c_write(addr & 0xff);
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if (!swi2c_wait_ack()) return 0;
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swi2c_write(*pbyte);
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if (!swi2c_wait_ack()) return 0;
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swi2c_stop();
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return 1;
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}
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#endif //SWI2C_A16
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#endif //SWI2C_SCL
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