source: firmware/FSC/src/FSC_test_electrical_connection.c@ 15819

//-----------------------------------------------------------------------------
#include "typedefs.h"
#include "application.h"
#include "spi_master.h"
#include "ad7719_adc.h"
#include "atmega_adc.h"    
#include "usart.h"
#include "macros.h"
#include "muxer_fsc.h"
#include "output.h"
#include "parser.h"
#include "interpol.h"
#include "w5100_spi_interface.h"
#include <avr/interrupt.h>
#include <avr/wdt.h>
#include <stdlib.h>
//-----------------------------------------------------------------------------
// definition of some functions:
// these function are implemented in this file, this is not doog coding style.
// sooner or later, they will be moved into more apropriate files.

void parse(); //doesn't do anything at the moment

// end of function definition:
//-----------------------------------------------------------------------------


// MAIN WORKFLOW GLOBAL VARIABLES
        bool verbose;
        bool heartbeat_enable;

// USART global variables
        U08 usart_rx_buffer[USART_RX_BUFFER_SIZE];
        U08 usart_tx_buffer[USART_TX_BUFFER_SIZE];
        U08 usart_rx_buffer_index = 0;
        U08 usart_tx_buffer_index = 0;
        U08 usart_last_char;                                    // last received char

// USART FLAGS
        bool usart_tx_buffer_overflow = false;  // true if usart_tx_buffer was full.
        //bool usart_rx_ready = false;                  // EOL was received, parser needs to be called
        
// TIMER global variable
        volatile U32 local_ms = 0;

// AD7719 global variables
        U32 ad7719_values[TEMP_CHANNELS];
        U08 ad7719_enables[CHANNEL_BITMAP];
        U08 ad7719_channels_ready[CHANNEL_BITMAP];
        U08 ad7719_readings_since_last_muxing = 0;
        U08 ad7719_current_channel = 0;
        U32 ad7719_current_reading = 0;
        bool ad7719_measured_all = false;
        
// ATMEGA ADC global variables
        U08 adc_values[V_CHANNELS + I_CHANNELS + H_CHANNELS]; // stores measured voltage in steps of 16mV
        U08 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP];
        U08 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP];
        U08 adc_readings_since_last_muxing = 0;
        U08 adc_current_channel = 0;
        U08 adc_current_reading = 0;
        bool adc_measured_all = false;

        bool once_told_you = true;
        bool debug_mode = false;
        
#ifndef ___MAIN_WORKFLOW_GLOBAL_VARS
#define ___MAIN_WORKFLOW_GLOBAL_VARS    
        #define TEMP_CHANNELS 64
        #define CHANNEL_BITMAP 8
        #define AD7719_READINGS_UNTIL_SETTLED 1 // bei3:480ms
        #define V_CHANNELS 40
        #define I_CHANNELS 40
        #define H_CHANNELS 4
        #define V_BITMAP 5
        #define I_BITMAP 5
        #define H_BITMAP 1
        #define ADC_READINGS_UNTIL_SETTLED 1
        
#endif // ___MAIN_WORKFLOW_GLOBAL_VARS


//-----------------------------------------------------------------------------
//   M A I N    ---   M A I N    ---   M A I N    ---   M A I N    ---  M A I N    
//-----------------------------------------------------------------------------
int main(void)
{
        U08 register_content;

        app_init();               // Setup: Watchdog and I/Os
        usart_init();

        spi_init();             // Initialize SPI interface as master
        
// TIMER2 is used as local clock:
// configure timer 2
        TCCR2 = (1<<WGM21); // CTC Modus
        TCCR2 |= (1<<CS21) | (1<<CS20); // Prescaler 64 --> counts up every 8us
        OCR2 = 125-1;                                   // --> output compare interrupt occurs every 125 x 8us = 1ms
        // Compare Interrupt erlauben
        TIMSK |= (1<<OCIE2);

  //  Enable interrupts
  sei();              

        usart_write_str((pU08)"Start of test firmware (06.05.11) now:\n");
        if (local_ms % 10000 == 0) {
                usart_write_str((pU08)"time: ");
                usart_write_U32(local_ms/1000,6);
                usart_write_str((pU08)"sec.\n");
        }

  PORTB &= ~(1<<PB2); //#reset = LOW --> W5100 is in reset ... 
        _delay_ms(50); //reset
        
        PORTB |= 1<<PB2; //#reset = HIGH --> W5100 is active
        _delay_ms(5);           // give it 5ms to accomodate.
        
        
//      DDRB |= (1 << PB2);  // setze 5tes bit im data direction register von port B
//      DDRB |= (1 << PB3);  // setze 5tes bit im data direction register von port B
//      DDRB |= (1 << PB4);  // setze 5tes bit im data direction register von port B
        
        while (1)
        { 
                PORTB ^= (1<<PB4);  // toggle zustand vom 5ten bit in Port B
                PORTB ^= (1<<PB3);  // toggle zustand vom 5ten bit in Port B
                PORTB ^= (1<<PB2);  // toggle zustand vom 5ten bit in Port B
                
        _delay_ms(1); //reset
                
        }
        
        
        while (1) {
        usart_write_str((pU08)"Start to read from W5300 CM_RTR0 register at:");
        usart_write_U32(local_ms,10);
        usart_write_str((pU08)"ms.\n");
        
        register_content = w5100_read(CM_RTR0); // read something
        
        usart_write_str((pU08)"register content of CM_RTR0 retrieved at:");
        usart_write_U32(local_ms,10);
        usart_write_str((pU08)"ms.\t");
        usart_write_str((pU08)"register content is: 0x");
        usart_write_U08_hex(register_content);
        usart_write_str((pU08)"\n");
        
        
        _delay_ms(400); //reset
        _delay_ms(400); //reset
        _delay_ms(400); //reset
}
        
        
        usart_write_str((pU08)"W5300 init begins at:");
        usart_write_U32(local_ms,10);
        usart_write_str((pU08)"ms.\n");
        
        w5100_init();
 
 
 
 

        
} // end of main()      
        
/*
//MAIN LOOP
while (1)
{
        if (heartbeat_enable) PORTB ^= (1<<PB3); // toggle Out2_spare --> heartbeat
//----------------------------------------------------------------------------
        //IF we need to send away one byte, and ready to send

        if ( (usart_tx_buffer_index > 0) && (UCSRA & (1<<UDRE)) ) { 
                UDR = usart_tx_buffer[0];
                // THis is shit
                for (U08 i=0 ; i < USART_TX_BUFFER_SIZE; ++i) {
                        usart_tx_buffer[i] = usart_tx_buffer[i+1];
                }
                usart_tx_buffer_index--;
        }
//----------------------------------------------------------------------------

        //IF we just received one byte, and there is enough space in the RX_buffer
        if ( (UCSRA & (1<<RXC)) && (usart_rx_buffer_index < USART_RX_BUFFER_SIZE) ){
                usart_last_char = UDR;
                if (usart_last_char == '\n'){ // if EOL was received
                        usart_rx_ready = true;
                }else {
                usart_rx_buffer[usart_rx_buffer_index] = usart_last_char;
                usart_rx_buffer_index++;
                }
                // here is still something strange .... better send an enter automatically
        } else if (UCSRA & (1<<RXC)) { // if there is no scace in the buffer; read anyway.
                usart_last_char = UDR;
                usart_rx_buffer_index =0;
        }
//----------------------------------------------------------------------------

        //IF USART DOR bit is set, PC is sending data to fast!!!
        if ( UCSRA & (1<<DOR) ){
                // flush TX_buffer and write warning message in
                // maybe even switch off every measurement. ?
        }
//----------------------------------------------------------------------------

        //IF TX_BUFFER was overrun.     
        if (usart_tx_buffer_overflow) {
                // flash TX_buffer and write warning message in
                // maybe even switch off every measurement. ?
                //
                // this should only happen, in verbose mode and with low baudrates.
        }
//----------------------------------------------------------------------------
        
        //IF one command was received. 
        //      -It is not allowed to send more than one command between two '\n'
        if (usart_rx_ready){ 
                parse();
                usart_rx_buffer_index = 0;
                usart_rx_ready = false;
        }
//----------------------------------------------------------------------------

        //IF ATmega internal ADC did finish a conversion --every 200us
        if ( (ADCSRA & (1<<ADIF)) && !adc_measured_all) {
                adc_current_reading = ADCH;
                if (adc_readings_since_last_muxing == ADC_READINGS_UNTIL_SETTLED) {
                        adc_values[adc_current_channel] = adc_current_reading;
                        adc_readings_since_last_muxing=0;
                        // note that this channel is ready, now and 
                        adc_output(adc_current_channel, adc_current_reading);
                        // proceed to the next enabled channel.
                        adc_channels_ready[adc_current_channel/8] |= (1<<(adc_current_channel%8));
                        adc_current_channel = increase_adc (adc_current_channel);
                        Set_V_Muxer(adc_current_channel);
                } else { // the ADC did not settle yet, we discard the reading
                        ++adc_readings_since_last_muxing;
                        // current reading is not used for anything else
                }
        }
//----------------------------------------------------------------------------

        //IF AD7719 ADC just finished a conversion -- every 60ms
        
        if (AD7719_IS_READY()) {
                        ad7719_current_reading = read_adc(); // --takes at 4MHz SCLK speed about 6us
                // AD7719 is only read out if settled. saves time.      
                if (ad7719_readings_since_last_muxing == AD7719_READINGS_UNTIL_SETTLED) {
                        ad7719_values[ad7719_current_channel] = ad7719_current_reading;
                        ad7719_readings_since_last_muxing=0;
                        // now prepare the data to be send away via USART.
                        //ad7719_output(ad7719_current_channel, ad7719_current_reading);
                        // note that this channel is ready, now and 
                        // proceed to the next enabled channel.
                        ad7719_channels_ready[ad7719_current_channel/8] |= (1<<(ad7719_current_channel%8));
                        ad7719_current_channel = increase_ad7719 (ad7719_current_channel);
                        Set_T_Muxer(ad7719_current_channel);
                } else { // the AD7719 did not settle yet, we discard the reading
                        ++ad7719_readings_since_last_muxing;

                        // current reading is not used for anything else
                }
        }
//----------------------------------------------------------------------------
        //IF one of the ADC measured all channels, we wanted to know.
        check_if_measured_all();
        
        if (ad7719_measured_all && adc_measured_all)
                adc_output_all();

//----------------------------------------------------------------------------

//      if (verbose == true)
                // talk() was just defined so the 
                // code is not at this place ... look down.
//              talk();


} // end of MAIN LOOP
//-----------------------------------------------------------------------------
//    E N D     E N D     E N D     E N D     E N D     E N D     E N D     
//-----------------------------------------------------------------------------

*/



ISR (TIMER2_COMP_vect)
{
 ++local_ms;
}