Mercurial > templog
view main.c @ 18:bf733e8e8cf0
Add INT0 button
author | Matt Johnston <matt@ucc.asn.au> |
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date | Tue, 22 May 2012 21:27:50 +0800 |
parents | 54b0fda9cba7 |
children | f1016b151689 |
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/* Name: main.c * Author: <insert your name here> * Copyright: <insert your copyright message here> * License: <insert your license reference here> */ #include <stdio.h> #include <string.h> #include <stddef.h> #include <avr/io.h> #include <avr/interrupt.h> #include <avr/sleep.h> #include <util/delay.h> #include <avr/pgmspace.h> #include <avr/eeprom.h> #include <util/crc16.h> // for DWORD of get_fattime() #include "integer.h" #include "simple_ds18b20.h" #include "onewire.h" // configuration params // - measurement interval // - transmit interval // - bluetooth params // - number of sensors (and range?) // 1 second. we have 1024 prescaler, 32768 crystal. #define SLEEP_COMPARE 32 #define MEASURE_WAKE 10 #define VALUE_NOSENSOR -9000 #define VALUE_BROKEN -8000 #define COMMS_WAKE 3600 #define BAUD 19200 #define UBRR ((F_CPU)/8/(BAUD)-1) #define PORT_LED PORTC #define DDR_LED DDRC #define PIN_LED PC4 #define PORT_SHDN PORTD #define DDR_SHDN DDRD #define PIN_SHDN PD7 #define NUM_MEASUREMENTS 100 #define MAX_SENSORS 5 // fixed at 8, have a shorter name #define ID_LEN OW_ROMCODE_SIZE int uart_putchar(char c, FILE *stream); static void long_delay(int ms); static FILE mystdout = FDEV_SETUP_STREAM(uart_putchar, NULL, _FDEV_SETUP_WRITE); static uint16_t n_measurements = 0; // stored as decidegrees static int16_t measurements[NUM_MEASUREMENTS][MAX_SENSORS]; // boolean flags static uint8_t need_measurement = 0; static uint8_t need_comms = 0; static uint8_t comms_done = 0; static uint8_t readpos = 0; static char readbuf[30]; static uint8_t measure_count = 0; static uint16_t comms_count = 0; // thanks to http://projectgus.com/2010/07/eeprom-access-with-arduino/ #define eeprom_read_to(dst_p, eeprom_field, dst_size) eeprom_read_block((dst_p), (void *)offsetof(struct __eeprom_data, eeprom_field), (dst_size)) #define eeprom_read(dst, eeprom_field) eeprom_read_to((&dst), eeprom_field, sizeof(dst)) #define eeprom_write_from(src_p, eeprom_field, src_size) eeprom_write_block((src_p), (void *)offsetof(struct __eeprom_data, eeprom_field), (src_size)) #define eeprom_write(src, eeprom_field) { eeprom_write_from(&src, eeprom_field, sizeof(src)); } #define EXPECT_MAGIC 0x67c9 struct __attribute__ ((__packed__)) __eeprom_data { uint16_t magic; uint8_t n_sensors; uint8_t sensor_id[MAX_SENSORS][ID_LEN]; }; #define DEBUG(str) printf_P(PSTR(str)) static void deep_sleep(); static void chip_setup() { // INT0 setup EIMSK = _BV(INT0); // set pullup PORTD |= _BV(PD2); } static void uart_on() { // Power reduction register //PRR &= ~_BV(PRUSART0); // baud rate UBRR0H = (unsigned char)(UBRR >> 8); UBRR0L = (unsigned char)UBRR; // set 2x clock, improves accuracy of UBRR UCSR0A |= _BV(U2X0); UCSR0B = _BV(RXCIE0) | _BV(RXEN0) | _BV(TXEN0); //8N1 UCSR0C = _BV(UCSZ01) | _BV(UCSZ00); } static void uart_off() { // Turn of interrupts and disable tx/rx UCSR0B = 0; // Power reduction register //PRR |= _BV(PRUSART0); } int uart_putchar(char c, FILE *stream) { // XXX should sleep in the loop for power. if (c == '\n') { loop_until_bit_is_set(UCSR0A, UDRE0); UDR0 = '\r';; } loop_until_bit_is_set(UCSR0A, UDRE0); UDR0 = c; if (c == '\r') { loop_until_bit_is_set(UCSR0A, UDRE0); UDR0 = '\n';; } return 0; } static void cmd_fetch() { uint16_t crc = 0; uint8_t n_sensors; eeprom_read(n_sensors, n_sensors); printf_P(PSTR("%d sensors\n"), n_measurements); for (uint8_t s = 0; s < n_sensors; s++) { uint8_t id[ID_LEN]; printf_P(PSTR("%d : "), s); eeprom_read_to(id, sensor_id[s], ID_LEN); printhex(id, ID_LEN); putchar('\n'); for (uint8_t i = 0; i < ID_LEN; i++) { crc = _crc_ccitt_update(crc, id[i]); } } printf_P(PSTR("%d measurements\n"), n_measurements); for (uint16_t n = 0; n < n_measurements; n++) { printf_P(PSTR("%3d :"), n); for (uint8_t s = 0; s < n_sensors; s++) { printf_P(PSTR(" %6d"), measurements[n][s]); crc = _crc_ccitt_update(crc, measurements[n][s]); } putchar('\n'); } printf_P(PSTR("CRC : %d\n"), crc); } static void cmd_clear() { n_measurements = 0; printf_P(PSTR("Cleared\n")); } static void cmd_btoff() { printf_P(PSTR("Turning off\n")); _delay_ms(50); PORTD |= _BV(PIN_SHDN); comms_done = 1; } static void cmd_measure() { printf_P(PSTR("Measuring\n")); need_measurement = 1; } static void cmd_sensors() { uint8_t ret = simple_ds18b20_start_meas(NULL); printf_P(PSTR("All sensors, ret %d, waiting...\n"), ret); long_delay(DS18B20_TCONV_12BIT); simple_ds18b20_read_all(); } // 0 on success static uint8_t get_hex_string(const char *hex, uint8_t *out, uint8_t size) { uint8_t upper; uint8_t o; for (uint8_t i = 0, z = 0; o < size; i++) { uint8_t h = hex[i]; if (h >= 'A' && h <= 'F') { // lower case h += 0x20; } uint8_t nibble; if (h >= '0' && h <= '9') { nibble = h - '0'; } else if (h >= 'a' && h <= 'f') { nibble = 10 + h - 'a'; } else if (h == ' ' || h == ':') { continue; } else { printf_P(PSTR("Bad hex 0x%x '%c'\n"), hex[i], hex[i]); return 1; } if (z % 2 == 0) { upper = nibble << 4; } else { out[o] = upper | nibble; o++; } z++; } if (o != size) { printf_P(PSTR("Short hex\n")); return 1; } return 0; } static void add_sensor(uint8_t *id) { uint8_t n; eeprom_read(n, n_sensors); if (n < MAX_SENSORS) { cli(); eeprom_write_from(id, sensor_id[n], ID_LEN); n++; eeprom_write(n, n_sensors); sei(); printf_P(PSTR("Added sensor %d : "), n); printhex(id, ID_LEN); putchar('\n'); } else { printf_P(PSTR("Too many sensors\n")); } } static void cmd_add_all() { uint8_t id[OW_ROMCODE_SIZE]; printf_P("Adding all\n"); ow_reset(); for( uint8_t diff = OW_SEARCH_FIRST; diff != OW_LAST_DEVICE; ) { diff = ow_rom_search( diff, &id[0] ); if( diff == OW_PRESENCE_ERR ) { printf_P( PSTR("No Sensor found\r") ); return; } if( diff == OW_DATA_ERR ) { printf_P( PSTR("Bus Error\r") ); return; } add_sensor(id); } } static void cmd_add_sensor(const char* hex_addr) { uint8_t id[ID_LEN]; uint8_t ret = get_hex_string(hex_addr, id, ID_LEN); if (ret) { return; } add_sensor(id); } static void cmd_init() { printf_P(PSTR("Resetting sensor list\n")); uint8_t zero = 0; cli(); eeprom_write(zero, n_sensors); sei(); printf_P(PSTR("Done.\n")); } static void check_first_startup() { uint16_t magic; eeprom_read(magic, magic); if (magic != EXPECT_MAGIC) { printf_P(PSTR("First boot, looking for sensors...\n")); cmd_init(); cmd_add_all(); cli(); magic = EXPECT_MAGIC; eeprom_write(magic, magic); sei(); } } static void cmd_toggle() { PORT_SHDN ^= _BV(PIN_SHDN); printf_P(PSTR("toggling power 3.3v %d\n"), PORT_SHDN & _BV(PIN_SHDN)); } static void read_handler() { if (strcmp_P(readbuf, PSTR("fetch")) == 0) { cmd_fetch(); } else if (strcmp_P(readbuf, PSTR("clear")) == 0) { cmd_clear(); } else if (strcmp_P(readbuf, PSTR("btoff")) == 0) { cmd_btoff(); } else if (strcmp_P(readbuf, PSTR("measure")) == 0) { cmd_measure(); } else if (strcmp_P(readbuf, PSTR("sensors")) == 0) { cmd_sensors(); } else if (strcmp_P(readbuf, PSTR("toggle")) == 0) { cmd_toggle(); } else if (strncmp_P(readbuf, PSTR("adds "), strlen("adds ")) == 0) { cmd_add_sensor(readbuf + strlen("adds ")); } else if (strcmp_P(readbuf, PSTR("addall"))== 0) { cmd_add_all(); } else if (strcmp_P(readbuf, PSTR("init")) == 0) { cmd_init(); } else { printf_P(PSTR("Bad command\n")); } } ISR(INT0_vwct) { need_comms = 1; } ISR(USART_RX_vect) { char c = UDR0; uart_putchar(c, NULL); if (c == '\r') { readbuf[readpos] = '\0'; read_handler(); readpos = 0; } else { readbuf[readpos] = c; readpos++; if (readpos >= sizeof(readbuf)) { readpos = 0; } } } ISR(TIMER2_COMPA_vect) { TCNT2 = 0; measure_count ++; comms_count ++; printf("measure_count %d\n", measure_count); if (measure_count >= MEASURE_WAKE) { measure_count = 0; printf("need_measurement = 1\n"); need_measurement = 1; } if (comms_count == COMMS_WAKE) { comms_count = 0; need_comms = 1; } } DWORD get_fattime (void) { return 0; } static void deep_sleep() { // p119 of manual OCR2A = SLEEP_COMPARE; loop_until_bit_is_clear(ASSR, OCR2AUB); set_sleep_mode(SLEEP_MODE_PWR_SAVE); sleep_mode(); } static void idle_sleep() { set_sleep_mode(SLEEP_MODE_IDLE); sleep_mode(); } #if 0 // untested static void do_adc_335() { //PRR &= ~_BV(PRADC); ADMUX = _BV(ADLAR); // ADPS2 = /16 prescaler, 62khz at 1mhz clock ADCSRA = _BV(ADEN) | _BV(ADPS2); // measure value ADCSRA |= _BV(ADSC); loop_until_bit_is_clear(ADCSRA, ADSC); uint8_t low = ADCL; uint8_t high = ADCH; uint16_t f_measure = low + (high << 8); // set to measure 1.1 reference ADMUX = _BV(ADLAR) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1); ADCSRA |= _BV(ADSC); loop_until_bit_is_clear(ADCSRA, ADSC); uint8_t low_11 = ADCL; uint8_t high_11 = ADCH; uint16_t f_11 = low_11 + (high_11 << 8); float res_volts = 1.1 * f_measure / f_11; // 10mV/degree // scale to 1/5 degree units above 0C int temp = (res_volts - 2.73) * 500; // XXX fixme //measurements[n_measurements] = temp; // XXX something if it hits the limit // measure AVR internal temperature against 1.1 ref. ADMUX = _BV(ADLAR) | _BV(MUX3) | _BV(REFS1) | _BV(REFS0); ADCSRA |= _BV(ADSC); loop_until_bit_is_clear(ADCSRA, ADSC); uint16_t res_internal = ADCL; res_internal |= ADCH << 8; float internal_volts = res_internal * (1.1 / 1024.0); // 1mV/degree int internal_temp = (internal_volts - 2.73) * 5000; // XXX fixme //internal_measurements[n_measurements] = internal_temp; printf_P("measure %d: external %d, internal %d, 1.1 %d\n", n_measurements, temp, internal_temp, f_11); n_measurements++; //PRR |= _BV(PRADC); } #endif static void do_measurement() { uint8_t n_sensors; printf("do_measurement\n"); eeprom_read(n_sensors, n_sensors); printf("do_measurement sensors %d\n", n_sensors); uint8_t ret = simple_ds18b20_start_meas(NULL); printf_P(PSTR("Read all sensors, ret %d, waiting...\n"), ret); _delay_ms(DS18B20_TCONV_12BIT); if (n_measurements == NUM_MEASUREMENTS) { printf_P(PSTR("Measurements .overflow\n")); n_measurements = 0; } for (uint8_t s = 0; s < MAX_SENSORS; s++) { int16_t decicelsius; if (s >= n_sensors) { decicelsius = VALUE_NOSENSOR; } else { uint8_t id[ID_LEN]; eeprom_read_to(id, sensor_id[s], ID_LEN); uint8_t ret = simple_ds18b20_read_decicelsius(id, &decicelsius); if (ret != DS18X20_OK) { decicelsius = VALUE_BROKEN; } } measurements[n_measurements][s] = decicelsius; } n_measurements++; //do_adc_335(); } static void do_comms() { need_comms = 0; // turn on bluetooth uart_on(); // write sd card here? same 3.3v regulator... printf("ready> \n"); comms_done = 0; for (;;) { if (comms_done) { break; } if (need_measurement) { need_measurement = 0; printf("measure from do_comms\n"); do_measurement(); } idle_sleep(); } uart_off(); // turn off bluetooth } static void blink() { PORT_LED &= ~_BV(PIN_LED); _delay_ms(1); PORT_LED |= _BV(PIN_LED); } static void long_delay(int ms) { int iter = ms / 100; for (int i = 0; i < iter; i++) { _delay_ms(100); } } ISR(BADISR_vect) { //uart_on(); printf_P(PSTR("Bad interrupt\n")); } static void set_2mhz() { cli(); CLKPR = _BV(CLKPCE); // divide by 4 CLKPR = _BV(CLKPS1); sei(); } int main(void) { set_2mhz(); DDR_LED |= _BV(PIN_LED); DDR_SHDN |= _BV(PIN_SHDN); blink(); stdout = &mystdout; uart_on(); fprintf_P(&mystdout, PSTR("hello %d\n"), 12); check_first_startup(); uart_off(); // turn off everything except timer2 //PRR = _BV(PRTWI) | _BV(PRTIM0) | _BV(PRTIM1) | _BV(PRSPI) | _BV(PRUSART0) | _BV(PRADC); // for testing uart_on(); sei(); // set up counter2. // COM21 COM20 Set OC2 on Compare Match (p116) // WGM21 Clear counter on compare //TCCR2A = _BV(COM2A1) | _BV(COM2A0) | _BV(WGM21); // toggle on match TCCR2A = _BV(COM2A0); // CS22 CS21 CS20 clk/1024 TCCR2B = _BV(CS22) | _BV(CS21) | _BV(CS20); // set async mode ASSR |= _BV(AS2); TCNT2 = 0; OCR2A = SLEEP_COMPARE; // interrupt TIMSK2 = _BV(OCIE2A); for (;;) { do_comms(); } for(;;){ /* insert your main loop code here */ if (need_measurement) { need_measurement = 0; do_measurement(); // testing cmd_fetch(); continue; } if (need_comms) { do_comms(); continue; } deep_sleep(); blink(); printf("."); } return 0; /* never reached */ }