/elec/propeller-clock : revision 59

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Committer: edam
Date: 2012-02-28 16:50:26 UTC
Revision ID: edam@waxworlds.org-20120228165026-pwnwo300xx2e2kg6

removed ulibc, fixed button, added text rendering

files added:
src/drawer.cc

src/drawer.h

src/major_mode.h

src/minor_mode.cc

src/minor_mode.h

src/mode_base.h

src/switcher_major_mode.cc

src/switcher_major_mode.h

files removed:
src/settings_mode.cc

src/settings_mode.h

src/text.cc

src/text.h

test/rtc-test

test/rtc-test/Makefile

test/rtc-test/rtc-ds1307.ino

test/rtc-test/util

test/rtc-test/util/DS1307.cpp

test/rtc-test/util/DS1307.h

files renamed:
src/analogue_clock.cc => src/analogue_clock_mode.cc

src/analogue_clock.h => src/analogue_clock_mode.h

src/digital_clock.cc => src/digital_clock_mode.cc

src/digital_clock.h => src/digital_clock_mode.h

src/common.cc => src/display.cc

src/common.h => src/display.h

src/propeller-clock.cc => src/propeller-clock.ino

src/test_pattern.cc => src/test_mode.cc

src/test_pattern.h => src/test_mode.h

files modified:
.bzrignore

arduino.mk

electronics-information

notes

src/Makefile

src/config.h

src/text_renderer.cc

src/text_renderer.h

src/time.cc

src/time.h

Show diffs side-by-side

added added

removed removed

src/propeller-clock.ino

* a PC fan is wired up to a 12V power supply

* the fan's SENSE (tachometer) pin connected to pin 2 on the

Arduino.

* the fan's SENSE (tachiometer) pin connected to pin 2 on the

arduino.

* the pins 4 to 13 on the Arduino should directly drive an LED (the

* the pins 4 to 13 on the arduino should directly drive an LED (the

LED on pin 4 is in the centre of the clock face and the LED on pin

13 is at the outside.

* if a longer hand (and a larger clock face) is desired, pin 4 can be

used to indirectly drive a transistor which in turn drives several

LEDs that turn on and off in unison in the centre of the clock.

LEDs that turn on anf off in unison in the centre of the clock.

* a button should be attached to pin 3 that grounds it when pressed.

* A DS1307 remote clock is connected via I2C on analogue pins 4 and 5.

* A DS1307 remote clock is connected via I2C on analog pins 4 and 5.

Implementation details:

* the timing of the drawing of the clock face is recalculated with

every rotation of the propeller.

* a PC fan actually sends 2 tachometer pulses per revolution, so the

* a PC fan actually sends 2 tachiometer pulses per revolution, so the

software skips every other one. This means that the clock may

appear upside-down if started with the propeller in the wrong

position. You will need to experiment to discover the position that

position. You will need to experiment to dicsover the position that

the propeller must be in when starting the clock.

Usage instructions:

******************************************************************************/

#include "config.h"

#include "display.h"

#include "button.h"

#include "time.h"

#include "Arduino.h"

#include "analogue_clock.h"

#include "digital_clock.h"

#include "test_pattern.h"

#include "settings_mode.h"

#include "text.h"

#include "text_renderer.h"

#include "common.h"

#include "switcher_major_mode.h"

#include "drawer.h"

//_____________________________________________________________________________

// data

// when non-zero, the time (in microseconds) of a new fan pulse that

// has just occurred, which means that segment drawing needs to be

// restarted

static unsigned long _new_pulse_at = 0;

static unsigned long new_pulse_at = 0;

// the time (in microseconds) when the last fan pulse occurred

static unsigned long _last_pulse_at = 0;

static unsigned long last_pulse_at = 0;

100

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// duration (in microseconds) that a segment should be displayed

102

static unsigned long _segment_step = 0;

static unsigned long segment_step = 0;

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// remainder after divisor and a tally of the remainders for each segment

105

static unsigned long _segment_step_sub_step = 0;

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static unsigned long _segment_step_sub = 0;

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static unsigned long segment_step_sub_step = 0;

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static unsigned long segment_step_sub = 0;

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// the button

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static Button _button( 3 );

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// modes

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static int _major_mode = 0;

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static int _minor_mode = 0;

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#define MAIN_MODE_IDX 1

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#define SETTINGS_MODE_IDX 0

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#define ANALOGUE_CLOCK_IDX 0

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#define DIGITAL_CLOCK_IDX 1

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#define TEST_PATTERN_IDX 2

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static Button button( 3 );

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// major mode

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static int major_mode = 0;

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#define MAX_MAJOR_MODES 5

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// major modes

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static MajorMode *major_modes[ MAX_MAJOR_MODES ] = { 0 };

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//_____________________________________________________________________________

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// code

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// activate the current minor mode

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void activate_minor_mode()

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{

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switch( _minor_mode ) {

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case ANALOGUE_CLOCK_IDX: analogue_clock_activate(); break;

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case DIGITAL_CLOCK_IDX: digital_clock_activate(); break;

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}

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// reset text

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Text::reset();

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leds_off();

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}

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// activate major mode

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void activate_major_mode()

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{

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switch( _major_mode ) {

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case MAIN_MODE_IDX: activate_minor_mode(); break;

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case SETTINGS_MODE_IDX: settings_mode_activate(); break;

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}

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// reset text

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Text::reset();

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leds_off();

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}

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// perform button events

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void do_button_events()

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void doButtonEvents()

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{

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// loop through pending events

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while( int event = _button.get_event() )

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while( int event = button.get_event() )

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{

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switch( event )

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{

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case 1:

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// short press

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switch( _major_mode ) {

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case MAIN_MODE_IDX:

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switch( _minor_mode ) {

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case ANALOGUE_CLOCK_IDX: analogue_clock_press(); break;

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case DIGITAL_CLOCK_IDX: digital_clock_press(); break;

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}

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break;

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case SETTINGS_MODE_IDX: settings_mode_press(); break;

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}

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major_modes[ major_mode ]->press();

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break;

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case 2:

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// long press

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switch( _major_mode ) {

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case MAIN_MODE_IDX:

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if( ++_minor_mode >= 3 )

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_minor_mode = 0;

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activate_minor_mode();

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break;

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case SETTINGS_MODE_IDX: settings_mode_long_press(); break;

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}

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major_modes[ major_mode ]->long_press();

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break;

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case 3:

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// looooong press (change major mode)

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if( ++_major_mode > 1 )

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_major_mode = 0;

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activate_major_mode();

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do {

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if( ++major_mode >= MAX_MAJOR_MODES )

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major_mode = 0;

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} while( major_modes[ major_mode ] == NULL );

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major_modes[ major_mode ]->activate();

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break;

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}

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}

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}

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// draw a display segment

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void draw_next_segment( bool reset )

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void drawNextSegment( bool reset )

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{

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// keep track of segment

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#if CLOCK_FORWARD

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if( reset ) segment = NUM_SEGMENTS - 1 - CLOCK_SHIFT;

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#endif

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// reset the text renderer

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TextRenderer::reset_buffer();

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// frame reset

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if( reset ) {

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switch( _major_mode ) {

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case MAIN_MODE_IDX:

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switch( _minor_mode ) {

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case ANALOGUE_CLOCK_IDX: analogue_clock_draw_reset(); break;

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case DIGITAL_CLOCK_IDX: digital_clock_draw_reset(); break;

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}

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break;

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case SETTINGS_MODE_IDX: settings_mode_draw_reset(); break;

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}

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// tell the text services we're starting a new frame

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Text::draw_reset();

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}

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// draw

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switch( _major_mode ) {

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case MAIN_MODE_IDX:

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switch( _minor_mode ) {

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case ANALOGUE_CLOCK_IDX: analogue_clock_draw( segment ); break;

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case DIGITAL_CLOCK_IDX: digital_clock_draw( segment ); break;

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case TEST_PATTERN_IDX: test_pattern_draw( segment ); break;

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}

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break;

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case SETTINGS_MODE_IDX: settings_mode_draw( segment ); break;

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}

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// draw any text that was rendered

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TextRenderer::output_buffer();

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Drawer &drawer = major_modes[ major_mode ]->get_drawer();

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if( reset ) drawer.draw_reset();

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drawer.draw( segment );

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#if CLOCK_FORWARD

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if( ++segment >= NUM_SEGMENTS ) segment = 0;

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// calculate time constants when a new pulse has occurred

253

void calculate_segment_times()

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void calculateSegmentTimes()

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{

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// check for overflows, and only recalculate times if there isn't

256

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// one (if there is, we'll just go with the last pulse's times)

257

if( _new_pulse_at > _last_pulse_at )

181

if( new_pulse_at > last_pulse_at )

258

182

{

259

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// new segment stepping times

260

unsigned long delta = _new_pulse_at - _last_pulse_at;

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_segment_step = delta / NUM_SEGMENTS;

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_segment_step_sub = 0;

263

_segment_step_sub_step = delta % NUM_SEGMENTS;

184

unsigned long delta = new_pulse_at - last_pulse_at;

185

segment_step = delta / NUM_SEGMENTS;

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segment_step_sub = 0;

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segment_step_sub_step = delta % NUM_SEGMENTS;

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}

265

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// now we have dealt with this pulse, save the pulse time and

267

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// clear new_pulse_at, ready for the next pulse

268

_last_pulse_at = _new_pulse_at;

269

_new_pulse_at = 0;

192

last_pulse_at = new_pulse_at;

193

new_pulse_at = 0;

270

194

}

271

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// wait until it is time to draw the next segment or a new pulse has

274

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// occurred

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void wait_till_end_of_segment( bool reset )

199

void waitTillEndOfSegment( bool reset )

276

200

{

277

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static unsigned long end_time = 0;

278

202

279

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// handle reset

280

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if( reset )

281

end_time = _last_pulse_at;

205

end_time = last_pulse_at;

282

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283

207

// work out the time that this segment should be displayed until

284

end_time += _segment_step;

285

_segment_step_sub += _segment_step_sub_step;

286

if( _segment_step_sub >= NUM_SEGMENTS ) {

287

_segment_step_sub -= NUM_SEGMENTS;

208

end_time += segment_step;

209

segment_step_sub += segment_step_sub_step;

210

if( segment_step_sub >= NUM_SEGMENTS ) {

211

segment_step_sub -= NUM_SEGMENTS;

288

212

end_time++;

289

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}

290

214

291

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// wait

292

while( micros() < end_time && !_new_pulse_at );

216

while( micros() < end_time && !new_pulse_at );

293

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}

294

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// ISR to handle the pulses from the fan's tachiometer

297

void fan_pulse_handler()

221

void fanPulseHandler()

298

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{

299

223

// the fan actually sends two pulses per revolution. These pulses

300

224

// may not be exactly evenly distributed around the rotation, so

305

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if( !ignore )

306

230

{

307

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// set a new pulse time

308

_new_pulse_at = micros();

232

new_pulse_at = micros();

309

233

}

310

234

}

311

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void setup()

315

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{

316

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// set up an interrupt handler on pin 2 to nitice fan pulses

317

attachInterrupt( 0, fan_pulse_handler, RISING );

241

attachInterrupt( 0, fanPulseHandler, RISING );

318

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digitalWrite( 2, HIGH );

319

243

320

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// set up output pins (4 to 13) for the led array

324

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// set up mode-switch button on pin 3

325

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pinMode( 3, INPUT );

326

250

digitalWrite( 3, HIGH );

327

static int event_times[] = { 5, 500, 4000, 0 };

328

_button.set_event_times( event_times );

329

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// initialise RTC

331

Time::init();

332

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// activate the minor mode

334

activate_major_mode();

251

static int event_times[] = { 5, 1000, 4000, 0 };

252

button.set_event_times( event_times );

253

254

// set up major modes

255

static SwitcherMajorMode switcher_major_mode;

256

int mode = 0;

257

major_modes[ mode++ ] = &switcher_major_mode;

258

major_modes[ 0 ]->activate();

335

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}

336

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void loop()

340

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{

341

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// if there has been a new pulse, we'll be resetting the display

342

bool reset = _new_pulse_at? true : false;

266

bool reset = new_pulse_at? true : false;

343

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// update button

345

_button.update();

269

button.update();

346

270

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// only do this stuff at the start of a display cycle, to ensure

348

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// that no state changes mid-display

349

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if( reset )

350

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{

351

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// calculate segment times

352

calculate_segment_times();

276

calculateSegmentTimes();

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// keep track of time

355

Time::update();

279

Time &time = Time::get_instance();

280

time.update();

356

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357

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// perform button events

358

do_button_events();

283

doButtonEvents();

359

284

}

360

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// draw this segment

362

draw_next_segment( reset );

287

drawNextSegment( reset );

363

288

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// wait till it's time to draw the next segment

365

wait_till_end_of_segment( reset );

290

waitTillEndOfSegment( reset );

366

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}

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