/** This routine writes the PIO bits
*
* \param id The serial number of the switch that is to be turned on or off
* \param state The PIO Status Bit Assignment. (2 LSBs)
* \return true(1): If set is successful
* false(0): If set is not successful
*/
uint8_t
ow_ds2413_write(uint8_t id[], uint8_t state)
{
uint8_t buff[5];
uint8_t wrByte;
wrByte = state | 0xFC;
// PIO Access Write Command
ow_command(0x5a, id);
// Channel write information
buff[1] = ow_byte_wr(wrByte);
// Inverted write byte
buff[2] = ow_byte_wr(~wrByte);
// Used to read the Status Bits
buff[3] = ow_byte_wr(0xFF);
// Used to read the PIO State
buff[4] = ow_byte_wr(0xFF);
if (buff[3] != 0xAA)
{
return false;
}
return true;
}
uint8_t DS18X20_write_scratchpad( uint8_t id[],
uint8_t th, uint8_t tl, uint8_t conf)
{
ow_reset(); //**
if( ow_input_pin_state() ) { // only send if bus is "idle" = high
ow_command( DS18X20_WRITE_SCRATCHPAD, id );
ow_byte_wr(th);
ow_byte_wr(tl);
if (id[0] == DS18B20_ID) ow_byte_wr(conf); // config avail. on B20 only
return DS18X20_OK;
}
else {
return DS18X20_ERROR;
}
}
/*************************************************************
Send command to specific device
**************************************************************/
void
ow_command( uint8_t command, uint8_t *id )
{ uint8_t i;
ow_reset();
if( id ) {
/* to a single device*/
ow_byte_wr( OW_MATCH_ROM );
i = OW_ROMCODE_SIZE;
do {
ow_byte_wr( *id );
id++;
} while( --i );
}
else /* to all devices*/ ow_byte_wr( OW_SKIP_ROM );
ow_byte_wr( command );
}
uint8_t DS18X20_write_scratchpad(uint8_t id[],
uint8_t th, uint8_t tl, uint8_t conf)
{
ow_reset(); //**
if (ow_input_pin_state()) { // only send if bus is "idle" = high
ow_command(DS18X20_WRITE_SCRATCHPAD, id);
ow_byte_wr(th);
ow_byte_wr(tl);
if (id[0] == DS18B20_ID) ow_byte_wr(conf); // config avail. on B20 only
return DS18X20_OK;
} else {
#ifdef DS18X20_VERBOSE
printf_P(PSTR("DS18X20_write_scratchpad: Short Circuit !\r"));
#endif
return DS18X20_ERROR;
}
}
/*
* Reads temp from the DS18B20
*/
double ds1820_read(void)
{
ADCSRA &= ~(1<<ADEN)|~(1<<ADSC);
uint8_t busy=0, temp1, temp2;
int16_t temp3;
double result;
ow_reset();
ow_byte_wr(0xCC);
ow_byte_wr(0x44);
while(busy == 0) {
busy = ow_byte_rd();
}
ow_reset();
ow_byte_wr(0xCC);
ow_byte_wr(0xBE);
temp1 = ow_byte_rd();
temp2 = ow_byte_rd();
/*onewire_write(0xCC); //Skip ROM, address all devices
onewire_write(0x44); //Start temperature conversion
while(busy == 0) //Wait while busy (bus is low)
busy = onewire_read();
onewire_reset();
onewire_write(0xCC); //Skip ROM, address all devices
onewire_write(0xBE); //Read scratchpad
temp1 = onewire_read();
temp2 = onewire_read();*/
temp3 = temp2;
temp3 = temp3 << 8;
temp3 = temp3 | temp1;
//result = (float) temp3 / 2.0; //Calculation for DS18S20 with 0.5 deg C resolution
result = (double) temp3 / 16.0; //Calculation for DS18B20
//_delay_ms(200);
return(result);
}
/** This routine reads the PIO bits
*
* \param id The serial number of the switch that is to be turned on or off
* \return true(1): If set is successful
* false(0): If set is not successful
*/
uint8_t
ow_ds2413_read(uint8_t id[])
{
// PIO Access Read Command
ow_command(0xf5, id);
// Used to read the PIO Status Bit Assignment
return ow_byte_wr(0xFF);
}
void ow_command( uint8_t command, const uint8_t id[] )
{
uint8_t i;
ow_reset();
if( id ) {
ow_byte_wr( OW_MATCH_ROM ); // to a single device
i = OW_ROMCODE_SIZE;
do {
ow_byte_wr( *id );
id++;
} while( --i );
}
else {
ow_byte_wr( OW_SKIP_ROM ); // to all devices
}
ow_byte_wr( command );
}
static void ow_command_intern( uint8_t command, uint8_t *id, uint8_t with_parasite_enable )
{
uint8_t i;
ow_reset();
if( id ) {
ow_byte_wr( OW_MATCH_ROM ); // to a single device
i = OW_ROMCODE_SIZE;
do {
ow_byte_wr( *id );
id++;
} while( --i );
}
else {
ow_byte_wr( OW_SKIP_ROM ); // to all devices
}
if ( with_parasite_enable ) {
ow_byte_wr_with_parasite_enable( command );
} else {
ow_byte_wr( command );
}
}
uint8_t ow_rom_search( uint8_t diff, uint8_t *id )
{
uint8_t i, j, next_diff;
uint8_t b;
if( ow_reset() ) {
return OW_PRESENCE_ERR; // error, no device found <--- early exit!
}
ow_byte_wr( OW_SEARCH_ROM ); // ROM search command
next_diff = OW_LAST_DEVICE; // unchanged on last device
i = OW_ROMCODE_SIZE * 8; // 8 bytes
do {
j = 8; // 8 bits
do {
b = ow_bit_io( 1 ); // read bit
if( ow_bit_io( 1 ) ) { // read complement bit
if( b ) { // 0b11
return OW_DATA_ERR; // data error <--- early exit!
}
}
else {
if( !b ) { // 0b00 = 2 devices
if( diff > i || ((*id & 1) && diff != i) ) {
b = 1; // now 1
next_diff = i; // next pass 0
}
}
}
ow_bit_io( b ); // write bit
*id >>= 1;
if( b ) {
*id |= 0x80; // store bit
}
i--;
} while( --j );
id++; // next byte
} while( i );
return next_diff; // to continue search
}
/***************************************
*
*
-***************************************/
uint8_t
ow_rom_search( uint8_t diff, uint8_t *id )
{ uint8_t i, j, next_diff;
uint8_t b;
if( ow_reset() ) return OW_PRESENCE_ERR;/* error, no device found*/
ow_byte_wr( OW_SEARCH_ROM ); /*ROM search command*/
next_diff = OW_LAST_DEVICE; /* unchanged on last device*/
i = OW_ROMCODE_SIZE * 8; /* 8 bytes*/
do {
j = 8; /* 8 bits*/
do{
b = ow_bit_io( 1 ); /* read bit*/
if( ow_bit_io( 1 ) ) {
/* read complement bit*/
if( b )/* 11*/ return OW_DATA_ERR; /* data error*/
}
else {
if( !b ) { /* 00 = 2 devices*/
if( diff > i || ((*id & 1) && diff != i) ) {
b = 1; /* now 1*/
next_diff = i; /* next pass 0*/
}
}
}
ow_bit_io( b ); /* write bit*/
*id >>= 1;
if( b ) *id |= 0x80;/* store bit*/
i--;
}
while( --j );
id++; /* next byte*/
}
while( i ); /* to continue search*/
return next_diff;
}
uint8_t ow_byte_rd( void )
{
// read by sending 0xff (a dontcare?)
return ow_byte_wr( 0xFF );
}
/* verbose output rom-search follows read-scratchpad in one loop */
uint8_t DS18X20_read_meas_all_verbose( void )
{
uint8_t id[OW_ROMCODE_SIZE], sp[DS18X20_SP_SIZE], diff;
uint8_t i;
uint16_t meas;
int16_t decicelsius;
char s[10];
uint8_t subzero, cel, cel_frac_bits;
for( diff = OW_SEARCH_FIRST; diff != OW_LAST_DEVICE; )
{
diff = ow_rom_search( diff, &id[0] );
if( diff == OW_PRESENCE_ERR ) {
uart_puts_P( "No Sensor found\r" );
return OW_PRESENCE_ERR; // <--- early exit!
}
if( diff == OW_DATA_ERR ) {
uart_puts_P( "Bus Error\r" );
return OW_DATA_ERR; // <--- early exit!
}
DS18X20_show_id_uart( id, OW_ROMCODE_SIZE );
if( id[0] == DS18B20_FAMILY_CODE || id[0] == DS18S20_FAMILY_CODE ||
id[0] == DS1822_FAMILY_CODE ) {
// temperature sensor
uart_putc ('\r');
ow_byte_wr( DS18X20_READ ); // read command
for ( i=0 ; i< DS18X20_SP_SIZE; i++ ) {
sp[i]=ow_byte_rd();
}
show_sp_uart( sp, DS18X20_SP_SIZE );
if ( crc8( &sp[0], DS18X20_SP_SIZE ) ) {
uart_puts_P( " CRC FAIL " );
} else {
uart_puts_P( " CRC O.K. " );
}
uart_putc ('\r');
meas = sp[0]; // LSB Temp. from Scrachpad-Data
meas |= (uint16_t) (sp[1] << 8); // MSB
uart_puts_P( " T_raw=");
uart_puthex_byte( (uint8_t)(meas >> 8) );
uart_puthex_byte( (uint8_t)meas );
uart_puts_P( " " );
if( id[0] == DS18S20_FAMILY_CODE ) { // 18S20
uart_puts_P( "S20/09" );
}
else if ( id[0] == DS18B20_FAMILY_CODE ||
id[0] == DS1822_FAMILY_CODE ) { // 18B20 or 1822
i=sp[DS18B20_CONF_REG];
if ( (i & DS18B20_12_BIT) == DS18B20_12_BIT ) {
uart_puts_P( "B20/12" );
}
else if ( (i & DS18B20_11_BIT) == DS18B20_11_BIT ) {
uart_puts_P( "B20/11" );
}
else if ( (i & DS18B20_10_BIT) == DS18B20_10_BIT ) {
uart_puts_P( " B20/10 " );
}
else { // if ( (i & DS18B20_9_BIT) == DS18B20_9_BIT ) {
uart_puts_P( "B20/09" );
}
}
uart_puts_P(" ");
DS18X20_meas_to_cel( id[0], sp, &subzero, &cel, &cel_frac_bits );
DS18X20_uart_put_temp( subzero, cel, cel_frac_bits );
decicelsius = DS18X20_raw_to_decicelsius( id[0], sp );
if ( decicelsius == DS18X20_INVALID_DECICELSIUS ) {
uart_puts_P("* INVALID *");
} else {
uart_puts_P(" conv: ");
uart_put_int(decicelsius);
uart_puts_P(" deci°C ");
DS18X20_format_from_decicelsius( decicelsius, s, 10 );
uart_puts_P(" fmt: ");
uart_puts(s);
uart_puts_P(" °C ");
}
uart_puts("\r");
} // if meas-sensor
} // loop all sensors
/* verbose output rom-search follows read-scratchpad in one loop */
uint8_t DS18X20_read_meas_all_verbose( void )
{
uint8_t id[OW_ROMCODE_SIZE], sp[DS18X20_SP_SIZE], diff;
uint8_t i;
uint16_t meas;
uint8_t subzero, cel, cel_frac_bits;
for( diff = OW_SEARCH_FIRST; diff != OW_LAST_DEVICE; )
{
diff = ow_rom_search( diff, &id[0] );
if( diff == OW_PRESENCE_ERR ) {
uart_puts_P( "No Sensor found\r\n" );
return OW_PRESENCE_ERR;
}
if( diff == OW_DATA_ERR ) {
uart_puts_P( "Bus Error\r\n" );
return OW_DATA_ERR;
}
DS18X20_show_id_uart( id, OW_ROMCODE_SIZE );
if( id[0] == DS18B20_ID || id[0] == DS18S20_ID ) { // temperature sensor
uart_puts_P ("\r\n");
ow_byte_wr( DS18X20_READ ); // read command
for ( i=0 ; i< DS18X20_SP_SIZE; i++ )
sp[i]=ow_byte_rd();
show_sp_uart( sp, DS18X20_SP_SIZE );
if ( crc8( &sp[0], DS18X20_SP_SIZE ) )
uart_puts_P( " CRC FAIL " );
else
uart_puts_P( " CRC O.K. " );
uart_puts_P ("\r\n");
meas = sp[0]; // LSB Temp. from Scrachpad-Data
meas |= (uint16_t) (sp[1] << 8); // MSB
uart_puts_P(" T_raw=");
uart_puthex_byte((uint8_t)(meas>>8));
uart_puthex_byte((uint8_t)meas);
uart_puts_P(" ");
if( id[0] == DS18S20_ID ) { // 18S20
uart_puts_P( "S20/09" );
}
else if ( id[0] == DS18B20_ID ) { // 18B20
i=sp[DS18B20_CONF_REG];
if ( (i & DS18B20_12_BIT) == DS18B20_12_BIT ) {
uart_puts_P( "B20/12" );
}
else if ( (i & DS18B20_11_BIT) == DS18B20_11_BIT ) {
uart_puts_P( "B20/11" );
}
else if ( (i & DS18B20_10_BIT) == DS18B20_10_BIT ) {
uart_puts_P( " B20/10 " );
}
else { // if ( (i & DS18B20_9_BIT) == DS18B20_9_BIT ) {
uart_puts_P( "B20/09" );
}
}
uart_puts_P(" ");
DS18X20_meas_to_cel(id[0], sp, &subzero, &cel, &cel_frac_bits);
DS18X20_uart_put_temp(subzero, cel, cel_frac_bits);
uart_puts("\r\n");
} // if meas-sensor
} // loop all sensors
uint8_t ow_byte_rd( void )
{
// read by sending only "1"s, so bus gets released
// after the init low-pulse in every slot
return ow_byte_wr( 0xFF );
}
