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286 lines
14 KiB
C
Executable File
286 lines
14 KiB
C
Executable File
/*! \file timer128.h \brief System Timer function library for Mega128. */
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//*****************************************************************************
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//
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// File Name : 'timer128.h'
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// Title : System Timer function library for Mega128
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// Author : Pascal Stang - Copyright (C) 2000-2003
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// Created : 11/22/2000
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// Revised : 02/10/2003
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// Version : 1.1
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// Target MCU : Atmel AVR Series
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// Editor Tabs : 4
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//
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// This code is distributed under the GNU Public License
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// which can be found at http://www.gnu.org/licenses/gpl.txt
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//
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//
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// Notes: The Atmel AVR Series Processors each contain at least one
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// hardware timer/counter. Many of the processors contain 2 or 3
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// timers. Generally speaking, a timer is a hardware counter inside
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// the processor which counts at a rate related to the main CPU clock
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// frequency. Because the counter value increasing (counting up) at
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// a precise rate, we can use it as a timer to create or measure
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// precise delays, schedule events, or generate signals of a certain
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// frequency or pulse-width.
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// As an example, the ATmega163 processor has 3 timer/counters.
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// Timer0, Timer1, and Timer2 are 8, 16, and 8 bits wide respectively.
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// This means that they overflow, or roll over back to zero, at a
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// count value of 256 for 8bits or 65536 for 16bits. A prescaler is
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// avaiable for each timer, and the prescaler allows you to pre-divide
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// the main CPU clock rate down to a slower speed before feeding it to
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// the counting input of a timer. For example, if the CPU clock
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// frequency is 3.69MHz, and Timer0's prescaler is set to divide-by-8,
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// then Timer0 will "tic" at 3690000/8 = 461250Hz. Because Timer0 is
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// an 8bit timer, it will count to 256 in just 256/461250Hz = 0.555ms.
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// In fact, when it hits 255, it will overflow and start again at
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// zero. In this case, Timer0 will overflow 461250/256 = 1801.76
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// times per second.
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// Timer0 can be used a number of ways simultaneously. First, the
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// value of the timer can be read by accessing the CPU register TCNT0.
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// We could, for example, figure out how long it takes to execute a
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// C command by recording the value of TCNT0 before and after
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// execution, then subtract (after-before) = time elapsed. Or we can
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// enable the overflow interrupt which goes off every time T0
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// overflows and count out longer delays (multiple overflows), or
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// execute a special periodic function at every overflow.
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// The other timers (Timer1 and Timer2) offer all the abilities of
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// Timer0 and many more features. Both T1 and T2 can operate as
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// general-purpose timers, but T1 has special hardware allowing it to
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// generate PWM signals, while T2 is specially designed to help count
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// out real time (like hours, minutes, seconds). See the
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// Timer/Counter section of the processor datasheet for more info.
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//
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//*****************************************************************************
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#ifndef TIMER128_H
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#define TIMER128_H
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#include "global.h"
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// constants/macros/typdefs
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// Timer/clock prescaler values and timer overflow rates
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// tics = rate at which the timer counts up
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// 8bitoverflow = rate at which the timer overflows 8bits (or reaches 256)
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// 16bit [overflow] = rate at which the timer overflows 16bits (65536)
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//
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// overflows can be used to generate periodic interrupts
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//
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// for 8MHz crystal
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// 0 = STOP (Timer not counting)
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// 1 = CLOCK tics= 8MHz 8bitoverflow= 31250Hz 16bit= 122.070Hz
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// 2 = CLOCK/8 tics= 1MHz 8bitoverflow= 3906.25Hz 16bit= 15.259Hz
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// 3 = CLOCK/64 tics= 125kHz 8bitoverflow= 488.28Hz 16bit= 1.907Hz
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// 4 = CLOCK/256 tics= 31250Hz 8bitoverflow= 122.07Hz 16bit= 0.477Hz
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// 5 = CLOCK/1024 tics= 7812.5Hz 8bitoverflow= 30.52Hz 16bit= 0.119Hz
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// 6 = External Clock on T(x) pin (falling edge)
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// 7 = External Clock on T(x) pin (rising edge)
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// for 4MHz crystal
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// 0 = STOP (Timer not counting)
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// 1 = CLOCK tics= 4MHz 8bitoverflow= 15625Hz 16bit= 61.035Hz
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// 2 = CLOCK/8 tics= 500kHz 8bitoverflow= 1953.125Hz 16bit= 7.629Hz
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// 3 = CLOCK/64 tics= 62500Hz 8bitoverflow= 244.141Hz 16bit= 0.954Hz
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// 4 = CLOCK/256 tics= 15625Hz 8bitoverflow= 61.035Hz 16bit= 0.238Hz
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// 5 = CLOCK/1024 tics= 3906.25Hz 8bitoverflow= 15.259Hz 16bit= 0.060Hz
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// 6 = External Clock on T(x) pin (falling edge)
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// 7 = External Clock on T(x) pin (rising edge)
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// for 3.69MHz crystal
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// 0 = STOP (Timer not counting)
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// 1 = CLOCK tics= 3.69MHz 8bitoverflow= 14414Hz 16bit= 56.304Hz
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// 2 = CLOCK/8 tics= 461250Hz 8bitoverflow= 1801.758Hz 16bit= 7.038Hz
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// 3 = CLOCK/64 tics= 57625.25Hz 8bitoverflow= 225.220Hz 16bit= 0.880Hz
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// 4 = CLOCK/256 tics= 14414.063Hz 8bitoverflow= 56.305Hz 16bit= 0.220Hz
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// 5 = CLOCK/1024 tics= 3603.516Hz 8bitoverflow= 14.076Hz 16bit= 0.055Hz
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// 6 = External Clock on T(x) pin (falling edge)
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// 7 = External Clock on T(x) pin (rising edge)
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// for 32.768KHz crystal on timer 2 (use for real-time clock)
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// 0 = STOP
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// 1 = CLOCK tics= 32.768kHz 8bitoverflow= 128Hz
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// 2 = CLOCK/8 tics= 4096kHz 8bitoverflow= 16Hz
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// 3 = CLOCK/64 tics= 512Hz 8bitoverflow= 2Hz
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// 4 = CLOCK/256 tics= 128Hz 8bitoverflow= 0.5Hz
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// 5 = CLOCK/1024 tics= 32Hz 8bitoverflow= 0.125Hz
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#define TIMER_CLK_STOP 0x00 ///< Timer Stopped
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#define TIMER_CLK_DIV1 0x01 ///< Timer clocked at F_CPU
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#define TIMER_CLK_DIV8 0x02 ///< Timer clocked at F_CPU/8
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#define TIMER_CLK_DIV64 0x03 ///< Timer clocked at F_CPU/64
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#define TIMER_CLK_DIV256 0x04 ///< Timer clocked at F_CPU/256
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#define TIMER_CLK_DIV1024 0x05 ///< Timer clocked at F_CPU/1024
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#define TIMER_CLK_T_FALL 0x06 ///< Timer clocked at T falling edge
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#define TIMER_CLK_T_RISE 0x07 ///< Timer clocked at T rising edge
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#define TIMER_PRESCALE_MASK 0x07 ///< Timer Prescaler Bit-Mask
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#define TIMERRTC_CLK_STOP 0x00 ///< RTC Timer Stopped
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#define TIMERRTC_CLK_DIV1 0x01 ///< RTC Timer clocked at F_CPU
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#define TIMERRTC_CLK_DIV8 0x02 ///< RTC Timer clocked at F_CPU/8
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#define TIMERRTC_CLK_DIV32 0x03 ///< RTC Timer clocked at F_CPU/32
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#define TIMERRTC_CLK_DIV64 0x04 ///< RTC Timer clocked at F_CPU/64
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#define TIMERRTC_CLK_DIV128 0x05 ///< RTC Timer clocked at F_CPU/128
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#define TIMERRTC_CLK_DIV256 0x06 ///< RTC Timer clocked at F_CPU/256
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#define TIMERRTC_CLK_DIV1024 0x07 ///< RTC Timer clocked at F_CPU/1024
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#define TIMERRTC_PRESCALE_MASK 0x07 ///< RTC Timer Prescaler Bit-Mask
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// default prescale settings for the timers
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// these settings are applied when you call
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// timerInit or any of the timer<x>Init
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#define TIMER0PRESCALE TIMERRTC_CLK_DIV64 ///< timer 0 prescaler default
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#define TIMER1PRESCALE TIMER_CLK_DIV64 ///< timer 1 prescaler default
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#define TIMER2PRESCALE TIMER_CLK_DIV8 ///< timer 2 prescaler default
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#define TIMER3PRESCALE TIMER_CLK_DIV64 ///< timer 3 prescaler default
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// interrupt macros for attaching user functions to timer interrupts
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// use these with timerAttach( intNum, function )
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// timer 0
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#define TIMER0OVERFLOW_INT 0
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#define TIMER0OUTCOMPARE_INT 1
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// timer 1
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#define TIMER1OVERFLOW_INT 2
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#define TIMER1OUTCOMPAREA_INT 3
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#define TIMER1OUTCOMPAREB_INT 4
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#define TIMER1OUTCOMPAREC_INT 5
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#define TIMER1INPUTCAPTURE_INT 6
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// timer 2
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#define TIMER2OVERFLOW_INT 7
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#define TIMER2OUTCOMPARE_INT 8
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// timer 3
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#define TIMER3OVERFLOW_INT 9
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#define TIMER3OUTCOMPAREA_INT 10
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#define TIMER3OUTCOMPAREB_INT 11
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#define TIMER3OUTCOMPAREC_INT 12
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#define TIMER3INPUTCAPTURE_INT 13
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#define TIMER_NUM_INTERRUPTS 14
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// type of interrupt handler to use for timers
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// *do not change unless you know what you're doing
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// Value may be SIGNAL or INTERRUPT
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#ifndef TIMER_INTERRUPT_HANDLER
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#define TIMER_INTERRUPT_HANDLER SIGNAL
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#endif
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// functions
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#define delay delay_us
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#define delay_ms timerPause
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void delay_us(unsigned short time_us);
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// initializes timing system
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// runs all timer init functions
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// sets all timers to default prescale values #defined in systimer.c
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void timerInit(void);
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// default initialization routines for each timer
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void timer0Init(void);
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void timer1Init(void);
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void timer2Init(void);
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void timer3Init(void);
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// Clock prescaler set/get commands for each timer/counter
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// For setting the prescaler, you should use one of the #defines
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// above like TIMER_CLK_DIVx, where [x] is the division rate
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// you want.
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// When getting the current prescaler setting, the return value
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// will be the [x] division value currently set.
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void timer0SetPrescaler(u08 prescale); ///< set timer0 prescaler division index
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void timer1SetPrescaler(u08 prescale); ///< set timer1 prescaler division index
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void timer2SetPrescaler(u08 prescale); ///< set timer2 prescaler division index
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void timer3SetPrescaler(u08 prescale); ///< set timer3 prescaler division index
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u16 timer0GetPrescaler(void); ///< get timer0 prescaler division rate
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u16 timer1GetPrescaler(void); ///< get timer1 prescaler division rate
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u16 timer2GetPrescaler(void); ///< get timer2 prescaler division rate
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u16 timer3GetPrescaler(void); ///< get timer3 prescaler division rate
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// TimerAttach and Detach commands
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// These functions allow the attachment (or detachment) of any user function
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// to a timer interrupt. "Attaching" one of your own functions to a timer
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// interrupt means that it will be called whenever that interrupt happens.
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// Using attach is better than rewriting the actual INTERRUPT() function
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// because your code will still work and be compatible if the timer library
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// is updated. Also, using Attach allows your code and any predefined timer
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// code to work together and at the same time. (ie. "attaching" your own
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// function to the timer0 overflow doesn't prevent timerPause from working,
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// but rather allows you to share the interrupt.)
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//
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// timerAttach(TIMER1OVERFLOW_INT, myOverflowFunction);
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// timerDetach(TIMER1OVERFLOW_INT)
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//
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// timerAttach causes the myOverflowFunction() to be attached, and therefore
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// execute, whenever an overflow on timer1 occurs. timerDetach removes the
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// association and executes no user function when the interrupt occurs.
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// myOverflowFunction must be defined with no return value and no arguments:
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//
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// void myOverflowFunction(void) { ... }
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void timerAttach(u08 interruptNum, void (*userFunc)(void) );
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void timerDetach(u08 interruptNum);
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// timing commands
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// timerPause pauses for the number of milliseconds specified in <pause_ms>
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void timerPause(unsigned short pause_ms);
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// overflow counters
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// to be documented
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void timer0ClearOverflowCount(void);
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long timer0GetOverflowCount(void);
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void timer2ClearOverflowCount(void);
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long timer2GetOverflowCount(void);
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// PWM initialization and set commands for timerX (where X is either 1 or 3)
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// timerXPWMInit()
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// configures the timerX hardware for PWM mode on pins OCXA, OCXB, and OCXC.
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// bitRes should be 8,9,or 10 for 8,9,or 10bit PWM resolution
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//
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// timerXPWMOff()
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// turns off all timerX PWM output and set timer mode to normal state
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//
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// timerXPWMAOn(), timerXPWMBOn(), timerXPWMCOn()
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// turn on output of PWM signals to OCXA,B,C pins
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// NOTE: Until you define the OCXA,B,C pins as outputs, and run
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// this "on" command, no PWM output will be output
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//
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// timerXPWMAOff(), timerXPWMBOff(), timerXPWMCOff()
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// turn off output of PWM signals to OCXA,B,C pins
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//
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// timerXPWMASet(), timer1PWMBSet(), timerXPWMCSet()
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// sets the PWM duty cycle for each channel
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// NOTE: <pwmDuty> should be in the range 0-255 for 8bit PWM
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// <pwmDuty> should be in the range 0-511 for 9bit PWM
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// <pwmDuty> should be in the range 0-1023 for 10bit PWM
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// NOTE: the PWM frequency can be controlled in increments by setting the
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// prescaler for timer1
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void timer1PWMInit(u08 bitRes); ///< initialize and set timer1 mode to PWM
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void timer1PWMInitICR(u16 topcount);///< initialize and set timer1 mode to PWM with specific top count
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void timer1PWMOff(void); ///< turn off all timer1 PWM output and set timer mode to normal
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void timer1PWMAOn(void); ///< turn on timer1 Channel A (OC1A) PWM output
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void timer1PWMBOn(void); ///< turn on timer1 Channel B (OC1B) PWM output
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void timer1PWMCOn(void); ///< turn on timer1 Channel C (OC1C) PWM output
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void timer1PWMAOff(void); ///< turn off timer1 Channel A (OC1A) PWM output
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void timer1PWMBOff(void); ///< turn off timer1 Channel B (OC1B) PWM output
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void timer1PWMCOff(void); ///< turn off timer1 Channel C (OC1C) PWM output
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void timer1PWMASet(u16 pwmDuty); ///< set duty of timer1 Channel A (OC1A) PWM output
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void timer1PWMBSet(u16 pwmDuty); ///< set duty of timer1 Channel B (OC1B) PWM output
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void timer1PWMCSet(u16 pwmDuty); ///< set duty of timer1 Channel C (OC1C) PWM output
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void timer3PWMInit(u08 bitRes); ///< initialize and set timer3 mode to PWM
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void timer3PWMInitICR(u16 topcount);///< initialize and set timer3 mode to PWM with specific top count
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void timer3PWMOff(void); ///< turn off all timer3 PWM output and set timer mode to normal
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void timer3PWMAOn(void); ///< turn on timer3 Channel A (OC3A) PWM output
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void timer3PWMBOn(void); ///< turn on timer3 Channel B (OC3B) PWM output
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void timer3PWMCOn(void); ///< turn on timer3 Channel C (OC3C) PWM output
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void timer3PWMAOff(void); ///< turn off timer3 Channel A (OC3A) PWM output
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void timer3PWMBOff(void); ///< turn off timer3 Channel B (OC3B) PWM output
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void timer3PWMCOff(void); ///< turn off timer3 Channel C (OC3C) PWM output
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void timer3PWMASet(u16 pwmDuty); ///< set duty of timer3 Channel A (OC3A) PWM output
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void timer3PWMBSet(u16 pwmDuty); ///< set duty of timer3 Channel B (OC3B) PWM output
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void timer3PWMCSet(u16 pwmDuty); ///< set duty of timer3 Channel C (OC3C) PWM output
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// Pulse generation commands have been moved to the pulse.c library
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#endif
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