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arduino--.h
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arduino--.h
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// -*- mode: c++; indent-tabs-mode: nil; -*-
#ifndef ARDUINO_MINUS_MINUS
#define ARDUINO_MINUS_MINUS
#include <avr/io.h>
#include <avr/interrupt.h>
#include <avr/sleep.h>
#include <util/delay.h>
#include <avr/pgmspace.h>
#include "avr-ports.h"
typedef uint8_t byte;
class ScopedInterruptDisable
{
public:
ScopedInterruptDisable() : sreg_(SREG) { cli(); }
~ScopedInterruptDisable() { SREG = sreg_; }
private:
byte sreg_;
};
template <byte reg> class _Register
{
public:
typedef byte value_t;
static void set(byte bit) { _SFR_IO8(reg) |= _BV(bit); }
static void clear(byte bit) { _SFR_IO8(reg) &= ~_BV(bit); }
static void write(byte val) { _SFR_IO8(reg) = val; }
static byte read() { return _SFR_IO8(reg); }
static void writeAnd(byte val) { _SFR_IO8(reg) &= val; }
static void writeOr(byte val) { _SFR_IO8(reg) |= val; }
static byte atomicRead()
{
ScopedInterruptDisable sid;
return _SFR_IO8(reg);
}
static void atomicWrite(byte val)
{
ScopedInterruptDisable sid;
_SFR_IO8(reg) = val;
}
void operator&=(byte bits) { _SFR_IO8(reg) &= bits; }
void operator|=(byte bits) { _SFR_IO8(reg) |= bits; }
void operator=(byte bits) { _SFR_IO8(reg) = bits; }
operator byte() const { return _SFR_IO8(reg); }
};
template <byte reg> class _Register16
{
public:
typedef uint16_t value_t;
static void setHigh(byte bit) { _SFR_IO8(reg + 1) |= _BV(bit); }
static void setLow(byte bit) { _SFR_IO8(reg) |= _BV(bit); }
static void clearHigh(byte bit) { _SFR_IO8(reg + 1) &= ~_BV(bit); }
static void clearLow(byte bit) { _SFR_IO8(reg) &= ~_BV(bit); }
static uint16_t read() { return _SFR_IO16(reg); }
static void write(uint16_t val) { _SFR_IO16(reg) = val; }
static uint16_t atomicRead()
{
ScopedInterruptDisable sid;
return _SFR_IO16(reg);
}
static void atomicWrite(uint16_t val)
{
ScopedInterruptDisable sid;
_SFR_IO16(reg) = val;
}
byte readLow() { return _SFR_IO8(reg); };
byte readHigh() { return _SFR_IO8(reg + 1); };
void operator&=(byte bits) { _SFR_IO8(reg) &= bits; }
void operator|=(byte bits) { _SFR_IO8(reg) |= bits; }
void operator=(uint16_t bits) { _SFR_IO16(reg) = bits; }
operator uint16_t() const { return _SFR_IO16(reg); }
};
/** An Output comparator, part of a timer
When new Timer types need to be implemented, make sure that:
* OCFx_ is on TIFR_
* OCIEx_ is on TIMSK_
* COM0_ and COM1_ are on TCCR_
* FOC_ is on TCCRF_
*/
template <class OCR_, class TCCR_, byte COM1_, byte COM0_,
class TIMSK_, byte OCIEx_,
class TIFR_, byte OCFx_,
class TCCRF_, byte FOC_>
class _OutputComparator
{
public:
static typename OCR_::value_t read() { return OCR_::read(); }
static void write(typename OCR_::value_t val) { OCR_::write(val); }
static void enableInterrupt(typename OCR_::value_t count)
{
// clear compare interrupt flag
TIFR_::set(OCFx_);
OCR_::write(count);
TIMSK_::set(OCIEx_);
}
static void enableInterrupt() { TIMSK_::set(OCIEx_); }
static void disableInterrupt() { TIMSK_::clear(OCIEx_); }
static void modeToggle() { TCCR_::set(COM0_); }
static void modeClear() { TCCR_::set(COM1_); }
static void modeSet() { TCCR_::write(_BV(COM1_) | _BV(COM0_)); }
static void disable()
{ TCCR_::writeAnd(~(_BV(COM0_) | _BV(COM1_))); }
/** Force the comparison of the output compare register.
Advanced functionality: This avoids a glitch in PWM generation
when the clock associated with this PWM Pin is not yet in a
PWM mode.
This method should not be called if the timer is already in
PWM mode.
So don't call this if you have called Arduino::init before.
*/
static void forceCompare() __attribute__((always_inline))
{
TCCRF_::set(FOC_);
}
};
/** A basic Timer with the counter register and overflow interrupt.
*/
template <class TCNT_, class TIMSK_, byte TOIE_>
class _Timer
{
public:
static void reset() { TCNT_::write(0); }
static typename TCNT_::value_t read() { return TCNT_::read(); }
static void write(typename TCNT_::value_t val) { TCNT_::write(val); }
static void enableOverflowInterrupt() { TIMSK_::set(TOIE_); }
static void disableOverflowInterrupt() { TIMSK_::clear(TOIE_); }
static void stop() { prescaler(0); }
typedef TCNT_ TCNT;
private:
// must be implemented by subclasses
static void prescaler(byte pre);
};
/** Hardware timer with 2 output compare units and 2 config registers
(TCCRA_ and TCCRB_)
This timer unit is used by the following devices: ATMega48/88/168/328
(Timer0 and Timer2)
The TCCRA_ register contains the following configuration bits (x=#timer):
@verbatim
+------+------+------+------+---+---+-----+-----+
|COMxA1|COMxA0|COMxB1|COMxB0| - | - |WGMx1|WGMx0|
+------+------+------+------+---+---+-----+-----+
@endverbatim
The TCCRB_ register contains the following configuration bits (x=#timer):
@verbatim
+-----+-----+---+---+-----+----+----+----+
|FOCxA|FOCxB| - | - |WGMx2|CSx2|CSx1|CSx0|
+-----+-----+---+---+-----+----+----+----+
@endverbatim
The TIMSK_ register contains the following configuration bits (x=#timer):
@verbatim
+---+---+---+---+---+------+------+-----+
| - | - | - | - | - |OCIExB|OCIExA|TOIEx|
+---+---+---+---+---+------+------+-----+
@endverbatim
The TIFR_ register contains the following configuration bits (x=#timer):
@verbatim
+---+---+---+---+---+-----+-----+----+
| - | - | - | - | - |OCFxB|OCFxA|TOVx|
+---+---+---+---+---+-----+-----+----+
@endverbatim
*/
template <class TCNT_, class OCRA_, class OCRB_, class TCCRA_, class TCCRB_,
class TIMSK_, class TIFR_>
class _Timer_2C : public _Timer<TCNT_, TIMSK_, 0> // 0 is TOIEx
{
public:
// TCCRA_
static const byte COMxA1 = 7, COMxA0 = 6, COMxB1 = 5, COMxB0 = 4;
static const byte WGMx1 = 1, WGMx0 = 0;
// TCCRB_
static const byte FOCxA = 7, FOCxB = 6;
static const byte WGMx2 = 3;
static const byte CSx2 = 2, CSx1 = 1, CSx0 = 0;
// TIMSK_
static const byte OCIExB = 2, OCIExA = 1;
static const byte TOIEx = 0;
// TIFR_
static const byte OCFxB = 2, OCFxA = 1;
static const byte TOVx = 0;
typedef _OutputComparator<OCRA_, TCCRA_, COMxA1, COMxA0, TIMSK_, OCIExA,
TIFR_, OCFxA, TCCRB_, FOCxA>
CompA;
typedef _OutputComparator<OCRB_, TCCRA_, COMxB1, COMxB0, TIMSK_, OCIExB,
TIFR_, OCFxB, TCCRB_, FOCxB>
CompB;
typedef TIFR_ TIFR;
static void prescaler1() { prescaler(_BV(CSx0)); }
static void prescaler8() { prescaler(_BV(CSx1)); }
static void prescaler64() { prescaler(_BV(CSx1) | _BV(CSx0)); }
static void prescaler256() { prescaler(_BV(CSx2)); }
static void prescaler1024() { prescaler(_BV(CSx2) | _BV(CSx0)); }
static void externalFalling() { prescaler(_BV(CSx2) | _BV(CSx1)); }
static void externalRising()
{ prescaler(_BV(CSx2) | _BV(CSx1) | _BV(CSx0)); }
static void modeNormal() { wgm(0); }
static void modePhaseCorrectPWM() { wgm(_BV(WGMx0)); }
static void modeClearTimerOnCompare() { wgm(_BV(WGMx1)); }
static void modeFastPWM() { wgm(_BV(WGMx1) | _BV(WGMx0)); }
static void modePhaseCorrectPWMOCRA() { wgm(_BV(WGMx2) | _BV(WGMx0)); }
static void modeFastPWMOCRA() { wgm(_BV(WGMx2) | _BV(WGMx1) | _BV(WGMx0)); }
private:
static void prescaler(byte pre)
{
byte tmp = TCCRB_::read() & ~7;
TCCRB_::write(tmp | pre);
}
static void wgm(byte waveform)
{
byte tmpb = TCCRB_::read() & ~_BV(WGMx2);
tmpb |= waveform & _BV(WGMx2);
TCCRB_::write(tmpb);
const byte mask10 = _BV(WGMx1) | _BV(WGMx0);
byte tmpa = TCCRA_::read() & ~mask10;
tmpa |= waveform & mask10;
TCCRA_::write(tmpa);
}
};
/** Hardware timer with 2 output compare units and 3 config registers
(TCCRA_ - TCCRC_)
This timer unit is used by the following devices: ATMega48/88/168/328
(Timer1)
The TCCRA_ register contains the following configuration bits (x=#timer):
@verbatim
+------+------+------+------+---+---+-----+-----+
|COMxA1|COMxA0|COMxB1|COMxB0| - | - |WGMx1|WGMx0|
+------+------+------+------+---+---+-----+-----+
@endverbatim
The TCCRB_ register contains the following configuration bits (x=#timer):
@verbatim
+-----+-----+---+-----+-----+----+----+----+
|ICNCx|ICESx| - |WGMx3|WGMx2|CSx2|CSx1|CSx0|
+-----+-----+---+-----+-----+----+----+----+
@endverbatim
TCCRC_ register contains the following configuration bits (x=#timer):
@verbatim
+-----+-----+---+---+---+---+---+---+
|FOCxA|FOCxB| - | - | - | - | - | - |
+-----+-----+---+---+---+---+---+---+
@endverbatim
The TIMSK_ register contains the following configuration bits (x=#timer):
@verbatim
+---+---+-----+---+---+------+------+-----+
| - | - |ICIEx| - | - |OCIExB|OCIExA|TOIEx|
+---+---+-----+---+---+------+------+-----+
@endverbatim
ICIEx is only available on _Timer_2C3.
The TIFR_ register contains the following configuration bits (x=#timer):
@verbatim
+---+---+----+---+---+-----+-----+----+
| - | - |ICFx| - | - |OCFxB|OCFxA|TOVx|
+---+---+----+---+---+-----+-----+----+
@endverbatim
ICFx is only available on _Timer_2C3.
*/
template <class TCNT_, class ICR_, class OCRA_, class OCRB_, class TCCRA_,
class TCCRB_, class TCCRC_, class TIMSK_, class TIFR_>
class _Timer_2C3 : public _Timer<TCNT_, TIMSK_, 0> // 0 is TOIEx
{
public:
// TCCRA_
static const byte COMxA1 = 7, COMxA0 = 6, COMxB1 = 5, COMxB0 = 4;
static const byte WGMx1 = 1, WGMx0 = 0;
// TCCRB_
static const byte ICNCx = 7, ICESx = 6;
static const byte WGMx3 = 4, WGMx2 = 3;
static const byte CSx2 = 2, CSx1 = 1, CSx0 = 0;
// TCCRC_
static const byte FOCxA = 7, FOCxB = 6;
// TIMSK_
static const byte ICIEx = 5;
static const byte OCIExB = 2, OCIExA = 1;
static const byte TOIEx = 0;
// TIFR_
static const byte ICFx = 5;
static const byte OCFxB = 2, OCFxA = 1;
static const byte TOVx = 0;
typedef ICR_ ICR;
typedef OCRA_ OCRA;
typedef OCRB_ OCRB;
typedef _OutputComparator<OCRA_, TCCRA_, COMxA1, COMxA0, TIMSK_, OCIExA,
TIFR_, OCFxA, TCCRB_, FOCxA>
CompA;
typedef _OutputComparator<OCRB_, TCCRA_, COMxB1, COMxB0, TIMSK_, OCIExB,
TIFR_, OCFxB, TCCRB_, FOCxB>
CompB;
static void prescaler1() { prescaler(_BV(CSx0)); }
static void prescaler8() { prescaler(_BV(CSx1)); }
static void prescaler64() { prescaler(_BV(CSx1) | _BV(CSx0)); }
static void prescaler256() { prescaler(_BV(CSx2)); }
static void prescaler1024() { prescaler(_BV(CSx2) | _BV(CSx0)); }
static void externalFalling() { prescaler(_BV(CSx2) | _BV(CSx1)); }
static void externalRising()
{ prescaler(_BV(CSx2) | _BV(CSx1) | _BV(CSx0)); }
static void modeNormal() { wgm(0); }
static void modePhaseCorrectPWM() { wgm(_BV(WGMx0)); }
static void modePhaseCorrectPWM9bit()
{ wgm(_BV(WGMx1) | _BV(WGMx0)); }
static void modePhaseCorrectPWM10bit()
{ wgm(_BV(WGMx2) | _BV(WGMx0)); }
static void modeClearTimerOnCompare() { wgm(_BV(WGMx2)); }
static void modeFastPWM() { wgm(_BV(WGMx2) | _BV(WGMx0)); }
static void modeFastPWM9bit() { wgm(_BV(WGMx2) | _BV(WGMx1)); }
static void modeFastPWM10bit()
{ wgm(_BV(WGMx2) | _BV(WGMx1) | _BV(WGMx1)); }
static void modePhaseAndFreqCorrectPWMICR()
{ wgm(_BV(WGMx3)); }
static void modePhaseAndFreqCorrectPWMOCRA()
{ wgm(_BV(WGMx3) | _BV(WGMx0)); }
static void modePhaseCorrectPWMICR()
{ wgm(_BV(WGMx3) | _BV(WGMx1)); }
static void modePhaseCorrectPWMOCRA()
{ wgm(_BV(WGMx3) | _BV(WGMx1) | _BV(WGMx0)); }
static void modeClearTimerOnCompareICR()
{ wgm(_BV(WGMx3) | _BV(WGMx2)); }
static void modeFastPWMICR() { wgm(_BV(WGMx3) | _BV(WGMx2) | _BV(WGMx1)); }
static void modeFastPWMOCRA()
{ wgm(_BV(WGMx3) | _BV(WGMx2) | _BV(WGMx1) | _BV(WGMx0)); }
private:
static void prescaler(byte pre)
{
const byte mask = _BV(CSx2) | _BV(CSx1) | _BV(CSx0);
byte tmp = TCCRB_::read() & ~mask;
TCCRB_::write(tmp |= pre);
}
static void wgm(byte waveform)
{
const byte mask32 = _BV(WGMx3) | _BV(WGMx2);
byte tmp32 = TCCRB_::read() & ~(mask32);
tmp32 |= waveform & mask32;
TCCRA_::write(tmp32);
const byte mask10 = _BV(WGMx1) | _BV(WGMx0);
byte tmp10 = TCCRA_::read() & ~mask10;
tmp10 |= waveform & mask10;
TCCRA_::write(tmp10);
}
};
/** Hardware timer with 3 output compare units and 2 config registers
(TCCR_ and GTCCR_)
This timer unit is used by the following devices: ATtiny25/45/85
(Timer1)
The TCCR_ register contains the following configuration bits (x=#timer):
@verbatim
+----+-----+------+------+----+----+----+----+
|CTCx|PWMxA|COMxA1|COMxA0|CSx3|CSx2|CSx1|CSx0|
+----+-----+------+------+----+----+----+----+
@endverbatim
The GTCCR_ register contains the following configuration bits (x=#timer):
@verbatim
+---+-----+------+------+-----+-----+----+----+
| - |PWMxB|COMxB1|COMxB0|FOCxB|FOCxA|PSR1|PSR0|
+---+-----+------+------+-----+-----+----+----+
@endverbatim
The TIMSK_ register contains the following configuration bits (x=#timer):
@verbatim
+---+------+------+---+---+-----+---+---+
| - |OCIExA|OCIExB| - | - |TOIEx| - | - |
+---+------+------+---+---+-----+---+---+
@endverbatim
The TIFR_ register contains the following configuration bits (x=#timer):
@verbatim
+---+-----+-----+---+---+---+----+---+
| - |OCFxA|OCFxB| - | - | - |TOVx| - |
+---+-----+-----+---+---+---+----+---+
@endverbatim
*/
template <class TCNT_, class OCRA_, class OCRB_, class OCRC_, class TCCR_,
class GTCCR_, class TIMSK_, class TIFR_>
class _TimerTiny_3C2 : public _Timer<TCNT_, TIMSK_, 2> // 2 is TOIEx
{
public:
// TCCR_
static const byte CTCx = 7;
static const byte PWMxA = 6;
static const byte COMxA1 = 5, COMxA0 = 4;
static const byte CSx3 = 3, CSx2 = 2, CSx1 = 1, CSx0 = 0;
// GTCCR_
static const byte PWMxB = 6;
static const byte COMxB1 = 5, COMxB0 = 4;
static const byte FOCxB = 3, FOCxA = 2;
static const byte PSR1 = 1, PSR0 = 0;
// TIMSK_
static const byte OCIExA = 6, OCIExB = 5;
static const byte TOIEx = 2;
// TIFR_
static const byte OCFxA = 6, OCFxB = 5;
static const byte TOVx = 1;
typedef OCRA_ OCRA;
typedef OCRB_ OCRB;
typedef OCRC_ OCRC;
typedef _OutputComparator<OCRA_, TCCR_, COMxA1, COMxA0, TIMSK_, OCIExA,
TIFR_, OCFxA, GTCCR_, FOCxA>
CompA;
typedef _OutputComparator<OCRB_, TCCR_, COMxB1, COMxB0, TIMSK_, OCIExB,
TIFR_, OCFxB, GTCCR_, FOCxB>
CompB;
static void stop() { prescaler(0); }
static void prescaler1() { prescaler(_BV(CSx0)); }
static void prescaler2() { prescaler(_BV(CSx1)); }
static void prescaler4() { prescaler(_BV(CSx1) | _BV(CSx0)); }
static void prescaler8() { prescaler(_BV(CSx2)); }
static void prescaler16() { prescaler(_BV(CSx2) | _BV(CSx0)); }
static void prescaler32() { prescaler(_BV(CSx2) | _BV(CSx1)); }
static void prescaler64() { prescaler(_BV(CSx2) | _BV(CSx1) | _BV(CSx0)); }
static void prescaler128() { prescaler(_BV(CSx3)); }
static void prescaler256() { prescaler(_BV(CSx3) | _BV(CSx0)); }
static void prescaler512() { prescaler(_BV(CSx3) | _BV(CSx1)); }
static void prescaler1024()
{ prescaler(_BV(CSx3) | _BV(CSx1) | _BV(CSx0)); }
static void prescaler2048() { prescaler(_BV(CSx3) | _BV(CSx2)); }
static void prescaler4096()
{ prescaler(_BV(CSx3) | _BV(CSx2) | _BV(CSx0)); }
static void prescaler8192()
{ prescaler(_BV(CSx3) | _BV(CSx2) | _BV(CSx1)); }
static void prescaler16384()
{ prescaler(_BV(CSx3) | _BV(CSx2) | _BV(CSx1) | _BV(CSx0)); }
static void modePWMA() { TCCR_::set(PWMxA); }
static void modePWMB() { GTCCR_::set(PWMxB); }
static void clearOnMatchOCRC() { TCCR_::set(CTCx); }
private:
static void prescaler(byte pre)
{
byte tmp = TCCR_::read() & ~15;
TCCR_::write(tmp |= pre);
}
};
/*
We are forcing gcc to inline the _Pin methods. I think this shouldn't be
necessary, but when the _Pin methods are used via a subclass like
_ChangeInterruptPin, gcc doesn't automatically inline these methods any more.
*/
template <byte ddr, byte port, byte in, byte bit>
class _Pin
{
public:
static void modeOutput() __attribute__((always_inline))
{ _SFR_IO8(ddr) |= _BV(bit); }
static void modeInput() __attribute__((always_inline))
{ _SFR_IO8(ddr) &= ~_BV(bit); }
static void modeInputPullup() __attribute__((always_inline))
{ modeInput(); set(); }
static void modeInputTristate() __attribute__((always_inline))
{ modeInput(); clear(); }
static void set() __attribute__((always_inline))
{ _SFR_IO8(port) |= _BV(bit); }
static void clear() __attribute__((always_inline))
{ _SFR_IO8(port) &= ~_BV(bit); }
/** Return 1 if the Pin reads HIGH */
static byte read() __attribute__((always_inline))
{ return !!(_SFR_IO8(in) & _BV(bit)); }
static byte toggle() __attribute__((always_inline))
{ return (_SFR_IO8(port) ^= _BV(bit)); }
};
template <class Pin_, class OCR_>
class _PWMPin : public Pin_
{
public:
/** Enable the Pin as an output and enable the noninverting PWM mode
on the output comparator.
Note: this does not enable PWM mode on the timer, that step needs to
be done separately.
*/
static void modePWM() __attribute__((always_inline))
{
Pin_::modeOutput();
OCR_::modeClear();
}
static void pwmOff() __attribute__((always_inline))
{
OCR_::disablePWM();
}
static void pwmWrite(byte value) __attribute__((always_inline))
{
OCR_::write(value);
}
};
// PCICR_ is the interrupt control register address, PCEN_ is the enable bit,
// PCMSK_ is pin change mask register and PCBIT_ the value bit
template <class Pin_, byte PCICR_, byte PCEN_, byte PCMSK_, byte PCBIT_>
class _ChangeInterruptPin : public Pin_
{
public:
static void enableChangeInterrupt() __attribute__((always_inline))
{
_SFR_IO8(PCICR_) |= _BV(PCEN_);
_SFR_IO8(PCMSK_) |= _BV(PCBIT_);
}
static void disableChangeInterrupt() __attribute__((always_inline))
{
if (_SFR_IO8(PCMSK_) &= ~_BV(PCBIT_))
_SFR_IO8(PCICR_) &= ~_BV(PCEN_);
}
};
#if defined (ADMUX) && defined (ADCSRA) && defined (ADSC) && defined (ADCH) \
&& defined (ADCL)
template <class Pin_, byte AIN_>
class _AnalogPin : public Pin_
{
static void analogStart(uint8_t reference) __attribute__((always_inline))
{
// set the analog reference (high two bits of ADMUX) and select the
// channel (low 4 bits). this also sets ADLAR (left-adjust result)
// to 0 (the default).
ADMUX = (reference << 6) | (AIN_ & 0x07);
// start the conversion
ADCSRA |= (1 << (ADSC));
}
static int analogRead(uint8_t reference)
{
analogStart(reference);
// ADSC is cleared when the conversion finishes
while (ADCSRA & (1 << 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.
uint8_t low = ADCL;
uint8_t high = ADCH;
// combine the two bytes
return (high << 8) | low;
}
};
#endif
class AVRBase
{
public:
static void interrupts() { sei(); }
static void noInterrupts() { cli(); }
};
/** Don't use this directly, use Clock16 or Clock32 instead
*/
template<typename timeres_t, class Timer> class _Clock
{
public:
typedef timeres_t time_res_t;
_Clock()
{
// enable timer overflow interrupt
Timer::enableOverflowInterrupt();
}
static timeres_t millis()
{
// disable interrupts while we read timer0millis or we might get an
// inconsistent value (e.g. in the middle of the timer_millis++)
ScopedInterruptDisable sid;
return timer_millis;
}
static uint16_t micros()
{
uint8_t m;
uint8_t t;
ScopedInterruptDisable sid;
t = Timer::TCNT::read();
m = timer_overflow_count % (1 << TIMER16_MICRO_SCALE);
if ((Timer::TIFR::read() & _BV(TOV0)) && (t == 0))
m++;
// FIXME: Timer::PRESCALE not actually defined yet, see CLOCK16_PRESCALE
return ((m << 8) + t) * (Timer::PRESCALE / (F_CPU / 1000000L));
}
static void delay(timeres_t ms)
{
const timeres_t start = millis();
while (millis() - start <= ms)
;
}
static void sleep(timeres_t ms)
{
const timeres_t start = millis();
set_sleep_mode(SLEEP_MODE_IDLE);
sleep_enable();
#ifdef sleep_bod_disable
sleep_bod_disable();
#endif
while (millis() - start <= ms)
{
sei();
sleep_cpu();
}
sei();
sleep_disable();
}
volatile static timeres_t timer_overflow_count;
volatile static uint16_t timer_fract;
volatile static timeres_t timer_millis;
};
template<typename timeres_t, class Timer>
volatile timeres_t _Clock<timeres_t, Timer>::timer_overflow_count = 0;
template<typename timeres_t, class Timer>
volatile uint16_t _Clock<timeres_t, Timer>::timer_fract = 0;
template<typename timeres_t, class Timer>
volatile timeres_t _Clock<timeres_t, Timer>::timer_millis = 0;
/** busy wait */
void delayMicroseconds(unsigned int us)
{
// calling avrlib's delay_us() function with low values (e.g. 1 or
// 2 microseconds) gives delays longer than desired.
//delay_us(us);
#if F_CPU >= 16000000L
// for the 16 MHz clock on most Arduino boards
// for a one-microsecond delay, simply return. the overhead
// of the function call yields a delay of approximately 1 1/8 us.
if (--us == 0)
return;
// the following loop takes a quarter of a microsecond (4 cycles)
// per iteration, so execute it four times for each microsecond of
// delay requested.
us <<= 2;
// account for the time taken in the preceeding commands.
us -= 2;
#else
// for the 8 MHz internal clock on the ATmega168
// for a one- or two-microsecond delay, simply return. the overhead of
// the function calls takes more than two microseconds. can't just
// subtract two, since us is unsigned; we'd overflow.
if (--us == 0)
return;
if (--us == 0)
return;
// the following loop takes half of a microsecond (4 cycles)
// per iteration, so execute it twice for each microsecond of
// delay requested.
us <<= 1;
// partially compensate for the time taken by the preceeding commands.
// we can't subtract any more than this or we'd overflow w/ small delays.
us--;
#endif
{
// disable interrupts, otherwise the timer 0 overflow interrupt that
// tracks milliseconds will make us delay longer than we want.
ScopedInterruptDisable sid;
// busy wait
__asm__ __volatile__ (
"1: sbiw %0,1" "\n\t" // 2 cycles
"brne 1b" : "=w" (us) : "0" (us) // 2 cycles
);
}
}
template <class Out> class HexWriter
{
public:
static void write(Out *out, byte b)
{
writeNibble(out, b >> 4);
writeNibble(out, b & 0x0f);
}
static void write(Out *out, uint16_t i)
{
write(out, static_cast<byte>(i >> 8));
write(out, static_cast<byte>(i & 0xff));
}
static void write(Out *out, const byte *b, byte n)
{
for (int k = 0; k < n; ++k)
write(out, b[k]);
}
static void writeNibble(Out *out, byte b)
{
if (b < 10)
out->write(b + '0');
else
out->write(b + 'a' - 10);
}
};
template <class Out> class StringWriter
{
public:
static void write(Out *out, const char *str)
{
while (*str)
out->write(*str++);
}
// PROGMEM variant
static void write_P(Out *out, const char *str)
{
byte v;
while ((v = pgm_read_byte(str++)))
out->write(v);
}
};
template <class Out> class DecimalWriter
{
public:
static void write(Out *out, uint32_t d, char digits)
{
if (d == 0 && digits <= 0)
return;
write(out, d/10, digits - 1);
out->write('0' + d % 10);
}
};
#if defined (__AVR_ATmega328P__) || defined (__AVR_ATmega328__) \
|| defined (__AVR_ATmega168__) || defined (__AVR_ATmega168A__) \
|| defined (__AVR_ATmega168P__)
#include "defs/mx8.h"
#elif defined (__AVR_ATtiny85__) || defined (__AVR_ATtiny45__) \
|| defined (__AVR_ATTiny25__)
#include "defs/tnx5.h"
#else
#error "No MCU specific definitions found"
#endif
#endif // ARDUINO_MINUS_MINUS