/* wiring.c - Wiring API Partial Implementation Part of Arduino / Wiring Lite Copyright (c) 2005 David A. Mellis This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA $Id: wiring.c,v 1.7 2005/05/28 21:04:15 mellis Exp $ */ #include #include #include #include #include #include #ifndef cbi #define cbi(sfr, bit) (_SFR_BYTE(sfr) &= ~_BV(bit)) #endif #ifndef sbi #define sbi(sfr, bit) (_SFR_BYTE(sfr) |= _BV(bit)) #endif // from Pascal's avrlib #include "global.h" //#include "a2d.h" #include "timer.h" #include "uart.h" // timer.h #defines delay to be delay_us, we need to undefine // it so our delay can be in milliseconds. #undef delay #include "wiring.h" // Get the hardware port of the given virtual pin number. This comes from // the pins_*.c file for the active board configuration. int digitalPinToPort(int pin) { return digital_pin_to_port[pin].port; } // Get the bit location within the hardware port of the given virtual pin. // This comes from the pins_*.c file for the active board configuration. int digitalPinToBit(int pin) { return digital_pin_to_port[pin].bit; } int analogOutPinToPort(int pin) { return analog_out_pin_to_port[pin].port; } int analogOutPinToBit(int pin) { return analog_out_pin_to_port[pin].bit; } int analogInPinToBit(int pin) { return analog_in_pin_to_port[pin].bit; } void pinMode(int pin, int mode) { if (digitalPinToPort(pin) != NOT_A_PIN) { if (mode == INPUT) cbi(_SFR_IO8(port_to_mode[digitalPinToPort(pin)]), digitalPinToBit(pin)); else sbi(_SFR_IO8(port_to_mode[digitalPinToPort(pin)]), digitalPinToBit(pin)); } } void digitalWrite(int pin, int val) { if (digitalPinToPort(pin) != NOT_A_PIN) { // If the pin that support PWM output, we need to turn it off // before doing a digital write. if (analogOutPinToBit(pin) == 1) timer1PWMAOff(); if (analogOutPinToBit(pin) == 2) timer1PWMBOff(); if (val == LOW) cbi(_SFR_IO8(port_to_output[digitalPinToPort(pin)]), digitalPinToBit(pin)); else sbi(_SFR_IO8(port_to_output[digitalPinToPort(pin)]), digitalPinToBit(pin)); } } int digitalRead(int pin) { if (digitalPinToPort(pin) != NOT_A_PIN) { // If the pin that support PWM output, we need to turn it off // before getting a digital reading. if (analogOutPinToBit(pin) == 1) timer1PWMAOff(); if (analogOutPinToBit(pin) == 2) timer1PWMBOff(); return (_SFR_IO8(port_to_input[digitalPinToPort(pin)]) >> digitalPinToBit(pin)) & 0x01; } return LOW; } /* int analogRead(int pin) { unsigned long start_time = millis(); int ch = analogInPinToBit(pin); volatile unsigned int low, high; //return a2dConvert10bit(ch); a2dSetChannel(ch); a2dStartConvert(); // wait until the conversion is complete or we // time out. without the timeout, this sometimes // becomes an infinite loop. page 245 of the atmega8 // datasheet says the conversion should take at most // 260 microseconds, so if two milliseconds have ticked // by, something's wrong. //while (!a2dIsComplete() && millis() - start_time < 50); while (!a2dIsComplete()); // a2Convert10bit sometimes read ADCL and ADCH in the // wrong order (?) causing it to sometimes miss reading, // especially if called multiple times in rapid succession. //return a2dConvert10bit(ch); //return ADCW; low = ADCL; high = ADCH; return (high << 8) | low; } */ int analogRead(int pin) { unsigned int low, high, ch = analogInPinToBit(pin); // the low 4 bits of ADMUX select the ADC channel ADMUX = (ADMUX & (unsigned int) 0xf0) | (ch & (unsigned int) 0x0f); // without a delay, we seem to read from the wrong channel delay(1); // start the conversion sbi(ADCSRA, ADSC); // ADSC is cleared when the conversion finishes while (bit_is_set(ADCSRA, ADSC)); // we have to read ADCL first; doing so locks both ADCL // and ADCH until ADCH is read. reading ADCL second would // cause the results of each conversion to be discarded, // as ADCL and ADCH would be locked when it completed. low = ADCL; high = ADCH; // combine the two bytes return (high << 8) | low; } // Right now, PWM output only works on the pins with // hardware support. These are defined in the appropriate // pins_*.c file. For the rest of the pins, we default // to digital output. void analogWrite(int pin, int val) { // We need to make sure the PWM output is enabled for those pins // that support it, as we turn it off when digitally reading or // writing with them. Also, make sure the pin is in output mode // for consistenty with Wiring, which doesn't require a pinMode // call for the analog output pins. if (analogOutPinToBit(pin) == 1) { pinMode(pin, OUTPUT); timer1PWMAOn(); timer1PWMASet(val); } else if (analogOutPinToBit(pin) == 2) { pinMode(pin, OUTPUT); timer1PWMBOn(); timer1PWMBSet(val); } else if (val < 128) digitalWrite(pin, LOW); else digitalWrite(pin, HIGH); } void beginSerial(int baud) { uartInit(); uartSetBaudRate(baud); } void serialWrite(unsigned char c) { uartSendByte(c); } int serialAvailable() { return uartGetRxBuffer()->datalength; } int serialRead() { return uartGetByte(); } void printMode(int mode) { // do nothing, we only support serial printing, not lcd. } void uartSendString(unsigned char *str) { while (*str) uartSendByte(*str++); } void print(const char *format, ...) { char buf[256]; va_list ap; va_start(ap, format); vsnprintf(buf, 256, format, ap); va_end(ap); uartSendString(buf); } unsigned long millis() { // timer 0 increments every timer0GetPrescaler() cycles, and // overflows when it reaches 256. we calculate the total // number of clock cycles, then divide by the number of clock // cycles per millisecond. return timer0GetOverflowCount() * timer0GetPrescaler() * 256L / F_CPU * 1000L; } void delay(unsigned long ms) { timerPause(ms); } int main(void) { sei(); // timer 0 is used for millis() and delay() timer0Init(); // timer 1 is used for the hardware pwm timer1Init(); timer1SetPrescaler(TIMER_CLK_DIV1); timer1PWMInit(8); //a2dInit(); //a2dSetPrescaler(ADC_PRESCALE_DIV128); // set a2d reference to AVCC (5 volts) cbi(ADMUX, REFS1); sbi(ADMUX, REFS0); // set a2d prescale factor to 128 // 16 MHz / 128 = 125 KHz, inside the desired 50-200 KHz range. // XXX: this will not work properly for other clock speeds, and // this code should use F_CPU to determine the prescale factor. sbi(ADCSRA, ADPS2); sbi(ADCSRA, ADPS1); sbi(ADCSRA, ADPS0); // enable a2d conversions sbi(ADCSRA, ADEN); setup(); for (;;) loop(); return 0; }