/elec/propeller-clock : revision 55

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Committer: edam
Date: 2012-02-25 01:29:52 UTC
Revision ID: tim@ed.am-20120225012952-32q8gg07aovk3qxh

updated arduino.mk

files added:
src/util/Bounce.cpp

src/util/Bounce.h

files removed:
src/analogue_clock.cc

src/analogue_clock.h

src/button.cc

src/button.h

src/common.cc

src/common.h

src/config.h

src/digital_clock.cc

src/digital_clock.h

src/settings_mode.cc

src/settings_mode.h

src/test_pattern.cc

src/test_pattern.h

src/text.cc

src/text.h

src/text_renderer.cc

src/text_renderer.h

src/time.cc

src/time.h

src/util/PString.cpp

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

files modified:
.bzrignore

arduino.mk

electronics-information

notes

src/Makefile

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 "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 <Bounce.h>

#include <DS1307.h>

#include <Wire.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

101

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

102

static unsigned long _segment_step = 0;

static unsigned long segment_step = 0;

103

104

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

105

static unsigned long _segment_step_sub_step = 0;

106

static unsigned long _segment_step_sub = 0;

107

108

// the button

109

static Button _button( 3 );

110

111

// modes

112

static int _major_mode = 0;

113

static int _minor_mode = 0;

114

115

#define MAIN_MODE_IDX 1

116

#define SETTINGS_MODE_IDX 0

117

118

#define ANALOGUE_CLOCK_IDX 0

119

#define DIGITAL_CLOCK_IDX 1

120

#define TEST_PATTERN_IDX 2

static unsigned long segment_step_sub_step = 0;

100

static unsigned long segment_step_sub = 0;

101

102

// flag to indicate that the drawing mode should be cycled to the next one

103

static bool inc_draw_mode = false;

104

105

// a bounce-managed button

106

static Bounce button( 3, 50 );

107

108

// the time

109

static int time_hours = 0;

110

static int time_minutes = 0;

111

static int time_seconds = 0;

112

113

// number of segments in a full display (rotation) is 60 (one per

114

// second) times the desired number of sub-divisions of a second

115

#define NUM_SECOND_SEGMENTS 5

116

#define NUM_SEGMENTS ( 60 * NUM_SECOND_SEGMENTS )

117

118

// clock draw direction

119

#define CLOCK_FORWARD 0

120

121

// rotate display (in segments)

122

#define CLOCK_SHIFT ( 58 * NUM_SECOND_SEGMENTS - 1 )

121

123

122

124

//_____________________________________________________________________________

123

125

// code

124

126

125

127

126

// activate the current minor mode

127

void activate_minor_mode()

128

{

129

// reset text

130

Text::reset();

131

leds_off();

132

133

// give the mode a chance to init

134

switch( _minor_mode ) {

135

case ANALOGUE_CLOCK_IDX: analogue_clock_activate(); break;

136

case DIGITAL_CLOCK_IDX: digital_clock_activate(); break;

137

}

138

}

139

140

141

// activate major mode

142

void activate_major_mode()

143

{

144

// reset text

145

Text::reset();

146

leds_off();

147

148

// give the mode a chance to init

149

switch( _major_mode ) {

150

case MAIN_MODE_IDX: activate_minor_mode(); break;

151

case SETTINGS_MODE_IDX: settings_mode_activate(); break;

152

}

153

}

154

155

156

// perform button events

157

void do_button_events()

158

{

159

// loop through pending events

160

while( int event = _button.get_event() )

161

{

162

switch( event )

163

{

164

case 1:

165

// short press

166

switch( _major_mode ) {

167

case MAIN_MODE_IDX:

168

switch( _minor_mode ) {

169

case ANALOGUE_CLOCK_IDX: analogue_clock_press(); break;

170

case DIGITAL_CLOCK_IDX: digital_clock_press(); break;

171

}

172

break;

173

case SETTINGS_MODE_IDX: settings_mode_press(); break;

174

}

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break;

176

177

case 2:

178

// long press

179

switch( _major_mode ) {

180

case MAIN_MODE_IDX:

181

if( ++_minor_mode >= 3 )

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_minor_mode = 0;

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activate_minor_mode();

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break;

185

case SETTINGS_MODE_IDX: settings_mode_long_press(); break;

186

}

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break;

188

189

case 3:

190

// 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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break;

128

// check for button presses

129

void checkButtons()

130

{

131

// update buttons

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button.update();

133

134

// notice button presses

135

if( button.risingEdge() )

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inc_draw_mode = true;

137

}

138

139

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// keep track of time

141

void trackTime()

142

{

143

// previous time and any carried-over milliseconds

144

static unsigned long last_time = millis();

145

static unsigned long carry = 0;

146

147

// how many milliseonds have elapsed since we last checked?

148

unsigned long next_time = millis();

149

unsigned long delta = next_time - last_time + carry;

150

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// update the previous time and carried-over milliseconds

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last_time = next_time;

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carry = delta % 1000;

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// add the seconds that have passed to the time

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time_seconds += delta / 1000;

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while( time_seconds >= 60 ) {

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time_seconds -= 60;

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time_minutes++;

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if( time_minutes >= 60 ) {

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time_minutes -= 60;

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time_hours++;

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if( time_hours >= 24 )

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time_hours -= 24;

195

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}

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}

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}

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// turn an led on/off

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void ledOn( int num, bool on )

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{

173

if( num < 0 || num > 9 ) return;

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// convert to pin no.

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num += 4;

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// pin 4 needs to be inverted (it's driving a PNP)

179

if( num == 4 ) on = !on;

180

181

digitalWrite( num, on? HIGH : LOW );

182

}

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// draw a segment for the test display

186

void drawNextSegment_test( int segment )

187

{

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// turn on outside LEDs

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ledOn( 9, true );

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// display segment number in binary across in the inside LEDs,

192

// with the LED on pin 12 showing the least-significant bit

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for( int a = 0; a < 9; a++ )

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ledOn( 8 - a, ( segment >> a ) & 1 );

195

}

196

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// draw a segment for the time display

199

void drawNextSegment_time( int segment )

200

{

201

int second = segment / NUM_SECOND_SEGMENTS;

202

int second_segment = segment % NUM_SECOND_SEGMENTS;

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// what needs to be drawn?

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bool draw_tick = ( !second_segment && second % 5 == 0 && second ) ||

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( second == 0 && second_segment == 1 ) ||

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( second == 59 && second_segment == NUM_SECOND_SEGMENTS - 1 );

208

bool draw_second = !second_segment && second == time_seconds;

209

bool draw_minute = !second_segment && second == time_minutes;

210

bool draw_hour = segment == time_hours * 5 * NUM_SECOND_SEGMENTS +

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( 5 * NUM_SECOND_SEGMENTS * time_minutes / 60 );

212

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// set the LEDs

214

ledOn( 9, true );

215

ledOn( 8, draw_tick || draw_second );

216

for( int a = 6; a <= 7; a++ )

217

ledOn( a, draw_minute || draw_second );

218

for( int a = 0; a <= 5; a++ )

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ledOn( a, draw_minute || draw_second || draw_hour );

220

}

221

222

200

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// draw a display segment

201

void draw_next_segment( bool reset )

224

void drawNextSegment( bool reset )

202

225

{

226

static int draw_mode = 0;

227

203

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// keep track of segment

204

229

#if CLOCK_FORWARD

205

230

static int segment = ( NUM_SEGMENTS - CLOCK_SHIFT ) % NUM_SEGMENTS;

209

234

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

210

235

#endif

211

236

212

// reset the text renderer

213

TextRenderer::reset_buffer();

214

215

// frame reset

216

if( reset ) {

217

switch( _major_mode ) {

218

case MAIN_MODE_IDX:

219

switch( _minor_mode ) {

220

case ANALOGUE_CLOCK_IDX: analogue_clock_draw_reset(); break;

221

case DIGITAL_CLOCK_IDX: digital_clock_draw_reset(); break;

222

}

223

break;

224

case SETTINGS_MODE_IDX: settings_mode_draw_reset(); break;

225

}

226

227

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

228

Text::draw_reset();

229

}

230

231

// draw

232

switch( _major_mode ) {

233

case MAIN_MODE_IDX:

234

switch( _minor_mode ) {

235

case ANALOGUE_CLOCK_IDX: analogue_clock_draw( segment ); break;

236

case DIGITAL_CLOCK_IDX: digital_clock_draw( segment ); break;

237

case TEST_PATTERN_IDX: test_pattern_draw( segment ); break;

238

}

239

break;

240

case SETTINGS_MODE_IDX: settings_mode_draw( segment ); break;

241

}

242

243

// draw any text that was rendered

244

TextRenderer::output_buffer();

237

// handle mode switch requests

238

if( reset && inc_draw_mode ) {

239

inc_draw_mode = false;

240

draw_mode++;

241

if( draw_mode >= 2 )

242

draw_mode = 0;

243

}

244

245

// draw the segment

246

switch( draw_mode ) {

247

case 0: drawNextSegment_test( segment ); break;

248

case 1: drawNextSegment_time( segment ); break;

249

}

245

250

246

251

#if CLOCK_FORWARD

247

252

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

252

257

253

258

254

259

// calculate time constants when a new pulse has occurred

255

void calculate_segment_times()

260

void calculateSegmentTimes()

256

261

{

257

262

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

258

263

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

259

if( _new_pulse_at > _last_pulse_at )

264

if( new_pulse_at > last_pulse_at )

260

265

{

261

266

// new segment stepping times

262

unsigned long delta = _new_pulse_at - _last_pulse_at;

263

_segment_step = delta / NUM_SEGMENTS;

264

_segment_step_sub = 0;

265

_segment_step_sub_step = delta % NUM_SEGMENTS;

267

unsigned long delta = new_pulse_at - last_pulse_at;

268

segment_step = delta / NUM_SEGMENTS;

269

segment_step_sub = 0;

270

segment_step_sub_step = delta % NUM_SEGMENTS;

266

271

}

267

272

268

273

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

269

274

// clear new_pulse_at, ready for the next pulse

270

_last_pulse_at = _new_pulse_at;

271

_new_pulse_at = 0;

275

last_pulse_at = new_pulse_at;

276

new_pulse_at = 0;

272

277

}

273

278

274

279

275

280

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

276

281

// occurred

277

void wait_till_end_of_segment( bool reset )

282

void waitTillNextSegment( bool reset )

278

283

{

279

284

static unsigned long end_time = 0;

280

285

281

286

// handle reset

282

287

if( reset )

283

end_time = _last_pulse_at;

288

end_time = last_pulse_at;

284

289

285

290

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

286

end_time += _segment_step;

287

_segment_step_sub += _segment_step_sub_step;

288

if( _segment_step_sub >= NUM_SEGMENTS ) {

289

_segment_step_sub -= NUM_SEGMENTS;

291

end_time += segment_step;

292

segment_step_sub += segment_step_sub_step;

293

if( segment_step_sub >= NUM_SEGMENTS ) {

294

segment_step_sub -= NUM_SEGMENTS;

290

295

end_time++;

291

296

}

292

297

293

298

// wait

294

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

299

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

295

300

}

296

301

297

302

298

303

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

299

void fan_pulse_handler()

304

void fanPulseHandler()

300

305

{

301

306

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

302

307

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

307

312

if( !ignore )

308

313

{

309

314

// set a new pulse time

310

_new_pulse_at = micros();

315

new_pulse_at = micros();

311

316

}

312

317

}

313

318

316

321

void setup()

317

322

{

318

323

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

319

attachInterrupt( 0, fan_pulse_handler, RISING );

324

attachInterrupt( 0, fanPulseHandler, RISING );

320

325

digitalWrite( 2, HIGH );

321

326

322

327

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

326

331

// set up mode-switch button on pin 3

327

332

pinMode( 3, INPUT );

328

333

digitalWrite( 3, HIGH );

329

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

330

_button.set_event_times( event_times );

331

332

// initialise RTC

333

Time::init();

334

335

// activate the minor mode

336

activate_major_mode();

334

335

// get the time from the real-time clock

336

int rtc_data[ 7 ];

337

RTC.get( rtc_data, true );

338

time_hours = rtc_data[ DS1307_HR ];

339

time_minutes = rtc_data[ DS1307_MIN ];

340

time_seconds = rtc_data[ DS1307_SEC ];

341

342

// serial comms

343

Serial.begin( 9600 );

337

344

}

338

345

339

346

341

348

void loop()

342

349

{

343

350

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

344

bool reset = _new_pulse_at? true : false;

345

346

// update button

347

_button.update();

351

bool reset = new_pulse_at? true : false;

348

352

349

353

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

350

354

// that no state changes mid-display

351

355

if( reset )

352

356

{

353

// calculate segment times

354

calculate_segment_times();

357

// check buttons

358

checkButtons();

355

359

356

360

// keep track of time

357

Time::update();

358

359

// perform button events

360

do_button_events();

361

trackTime();

361

362

}

362

363

364

// draw this segment

364

draw_next_segment( reset );

365

drawNextSegment( reset );

366

367

// do we need to recalculate segment times?

368

if( reset )

369

calculateSegmentTimes();

365

370

366

371

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

367

wait_till_end_of_segment( reset );

372

waitTillNextSegment( reset );

368

373

}

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