Merge pull request 'Merge with new EQ Code' (#2) from dcoredump/MicroDexed:dev into dev

Reviewed-on: https://codeberg.org/positionhigh/MicroDexed/pulls/2
pull/76/head
positionhigh 3 years ago
commit 82b7665656
  1. 72
      MicroDexed.ino
  2. 187
      UI.hpp
  3. 176
      UI_FX.h
  4. 176
      UI_FX_T4.h
  5. 87
      config.h
  6. 143
      control_sgtl5000plus.cpp
  7. 80
      control_sgtl5000plus.h
  8. 74
      dexed_sd.cpp
  9. 188
      sgtl5000_graphic_eq.hpp
  10. BIN
      third-party/TeensyTimerTool-master.zip
  11. 21
      third-party/TeensyTimerTool/LICENSE
  12. 7
      third-party/TeensyTimerTool/README.md
  13. BIN
      third-party/TeensyTimerTool/assets/FTM0_8CH.jpg
  14. 31
      third-party/TeensyTimerTool/examples/01_Basic/ArrayOfTimers/ArrayOfTimers.ino
  15. 3
      third-party/TeensyTimerTool/examples/01_Basic/ArrayOfTimers/README.md
  16. 26
      third-party/TeensyTimerTool/examples/01_Basic/HelloOneShot/HelloOneShot.ino
  17. 29
      third-party/TeensyTimerTool/examples/01_Basic/HelloPeriodic/HelloPeriodic.ino
  18. 52
      third-party/TeensyTimerTool/examples/01_Basic/MoreTimers/MoreTimers.ino
  19. 35
      third-party/TeensyTimerTool/examples/01_Basic/UsingChronoDurations1/UsingChronoDurations1.ino
  20. 33
      third-party/TeensyTimerTool/examples/01_Basic/UsingChronoDurations2/UsingChronoDurations2.ino
  21. 29
      third-party/TeensyTimerTool/examples/02_Advanced/CallbackWithParams/CallbackWithParams.ino
  22. 21
      third-party/TeensyTimerTool/examples/02_Advanced/UsingLambdas/UsingLambdas.ino
  23. 253
      third-party/TeensyTimerTool/examples/02_Advanced/UsingLambdas/pins.h
  24. 38
      third-party/TeensyTimerTool/examples/03_Applications/DoubleExposure/DoubleExposure.ino
  25. 32
      third-party/TeensyTimerTool/examples/03_Applications/DoubleExposure/LaserController.h
  26. 61
      third-party/TeensyTimerTool/examples/03_Applications/DoubleExposure/PulseGenerator.h
  27. 1
      third-party/TeensyTimerTool/examples/03_Applications/DoubleExposure/README.md
  28. 63
      third-party/TeensyTimerTool/examples/03_Applications/DoubleExposure/SystemController.h
  29. 39
      third-party/TeensyTimerTool/examples/99_Misc/PinInformation/GPIO_Info.h
  30. 213
      third-party/TeensyTimerTool/examples/99_Misc/PinInformation/PWM_TimerInfo.c
  31. 62
      third-party/TeensyTimerTool/examples/99_Misc/PinInformation/PWM_TimerInfo.h
  32. 17
      third-party/TeensyTimerTool/examples/99_Misc/PinInformation/PinInfo.h
  33. 53
      third-party/TeensyTimerTool/examples/99_Misc/PinInformation/PinInformation.ino
  34. 21
      third-party/TeensyTimerTool/library.json
  35. 10
      third-party/TeensyTimerTool/library.properties
  36. 17
      third-party/TeensyTimerTool/src/ESP32-dummy/TCK/TCK.cpp
  37. 79
      third-party/TeensyTimerTool/src/ESP32-dummy/TCK/TCK.h
  38. 89
      third-party/TeensyTimerTool/src/ESP32-dummy/TCK/TckChannel.h
  39. 40
      third-party/TeensyTimerTool/src/ErrorHandling/error_codes.h
  40. 79
      third-party/TeensyTimerTool/src/ErrorHandling/error_handler.cpp
  41. 17
      third-party/TeensyTimerTool/src/ErrorHandling/error_handler.h
  42. 48
      third-party/TeensyTimerTool/src/ITimerChannel.h
  43. 91
      third-party/TeensyTimerTool/src/Teensy/FTM/FTM.h
  44. 120
      third-party/TeensyTimerTool/src/Teensy/FTM/FTM_Channel.h
  45. 17
      third-party/TeensyTimerTool/src/Teensy/FTM/FTM_ChannelInfo.h
  46. 110
      third-party/TeensyTimerTool/src/Teensy/FTM/FTM_Info.h
  47. 77
      third-party/TeensyTimerTool/src/Teensy/GPT/GPT.h
  48. 116
      third-party/TeensyTimerTool/src/Teensy/GPT/GPTChannel.h
  49. 32
      third-party/TeensyTimerTool/src/Teensy/GPT/GPTmap.h
  50. 13
      third-party/TeensyTimerTool/src/Teensy/PIT4/PIT.cpp
  51. 70
      third-party/TeensyTimerTool/src/Teensy/PIT4/PIT.h
  52. 152
      third-party/TeensyTimerTool/src/Teensy/PIT4/PITChannel.h
  53. 32
      third-party/TeensyTimerTool/src/Teensy/PIT4/PITMap.h
  54. 41
      third-party/TeensyTimerTool/src/Teensy/TCK/TCK.cpp
  55. 82
      third-party/TeensyTimerTool/src/Teensy/TCK/TCK.h
  56. 336
      third-party/TeensyTimerTool/src/Teensy/TCK/TckChannel.h
  57. 15
      third-party/TeensyTimerTool/src/Teensy/TCK/TckChannelBase.h
  58. 100
      third-party/TeensyTimerTool/src/Teensy/TMR/TMR.h
  59. 178
      third-party/TeensyTimerTool/src/Teensy/TMR/TMRChannel.h
  60. 9
      third-party/TeensyTimerTool/src/TeensyTimerTool.h
  61. 10
      third-party/TeensyTimerTool/src/Timer.cpp
  62. 14
      third-party/TeensyTimerTool/src/Uno-dummy/TCK/TCK.cpp
  63. 79
      third-party/TeensyTimerTool/src/Uno-dummy/TCK/TCK.h
  64. 89
      third-party/TeensyTimerTool/src/Uno-dummy/TCK/TckChannel.h
  65. 22
      third-party/TeensyTimerTool/src/baseTimer.cpp
  66. 116
      third-party/TeensyTimerTool/src/baseTimer.h
  67. 66
      third-party/TeensyTimerTool/src/boardDef.h
  68. 88
      third-party/TeensyTimerTool/src/config.cpp
  69. 7
      third-party/TeensyTimerTool/src/config.h
  70. 91
      third-party/TeensyTimerTool/src/defaultConfig.h
  71. 406
      third-party/TeensyTimerTool/src/frequency.h
  72. 66
      third-party/TeensyTimerTool/src/oneShotTimer.h
  73. 22
      third-party/TeensyTimerTool/src/periodicTimer.h
  74. 34
      third-party/TeensyTimerTool/src/timer.h
  75. 30
      third-party/TeensyTimerTool/src/types.h

@ -52,7 +52,7 @@ using namespace TeensyTimerTool;
#endif
#endif
#ifdef SGTL5000_AUDIO_ENHANCE
#include "sgtl5000_graphic_eq.hpp"
#include "control_sgtl5000plus.h"
#endif
// Audio engines
@ -118,7 +118,11 @@ AudioMixer8 drum_reverb_send_mixer_l;
// Outputs
#if defined(TEENSY_AUDIO_BOARD)
AudioOutputI2S i2s1;
AudioControlSGTL5000 sgtl5000_1;
#ifdef SGTL5000_AUDIO_ENHANCE
AudioControlSGTL5000Plus sgtl5000(7);
#else
AudioControlSGTL5000 sgtl5000;
#endif
#elif defined (I2S_AUDIO_ONLY)
AudioOutputI2S i2s1;
#elif defined(TGA_AUDIO_BOARD)
@ -409,36 +413,34 @@ void setup()
AudioMemory(AUDIO_MEM);
#if defined(TEENSY_AUDIO_BOARD)
sgtl5000_1.enable();
sgtl5000_1.lineOutLevel(SGTL5000_LINEOUT_LEVEL);
sgtl5000_1.dacVolumeRamp();
sgtl5000_1.dacVolume(1.0);
//sgtl5000_1.dacVolumeRampLinear();
//sgtl5000_1.dacVolumeRampDisable();
sgtl5000_1.unmuteHeadphone();
sgtl5000_1.unmuteLineout();
sgtl5000_1.volume(SGTL5000_HEADPHONE_VOLUME, SGTL5000_HEADPHONE_VOLUME); // Headphone volume
sgtl5000.enable();
sgtl5000.lineOutLevel(SGTL5000_LINEOUT_LEVEL);
sgtl5000.dacVolumeRamp();
sgtl5000.dacVolume(1.0);
//sgtl5000.dacVolumeRampLinear();
//sgtl5000.dacVolumeRampDisable();
sgtl5000.unmuteHeadphone();
sgtl5000.unmuteLineout();
sgtl5000.volume(SGTL5000_HEADPHONE_VOLUME, SGTL5000_HEADPHONE_VOLUME); // Headphone volume
#ifdef SGTL5000_AUDIO_THRU
//sgtl5000_1.audioPreProcessorEnable();
sgtl5000_1.inputSelect(AUDIO_INPUT_LINEIN);
sgtl5000_1.lineInLevel(5);
//sgtl5000_1.adcHighPassFilterEnable();
//sgtl5000.audioPreProcessorEnable();
sgtl5000.inputSelect(AUDIO_INPUT_LINEIN);
sgtl5000.lineInLevel(5);
//sgtl5000.adcHighPassFilterEnable();
#endif
#ifdef SGTL5000_AUDIO_ENHANCE
sgtl5000_1.audioPostProcessorEnable();
sgtl5000_1.enhanceBassEnable();
sgtl5000_1.enhanceBass(1.0, 1.5, 0, 5); // enhanceBass(1.0, 1.0, 1, 2); // Configures the bass enhancement by setting the levels of the original stereo signal and the bass-enhanced mono level which will be mixed together. The high-pass filter may be enabled (0) or bypassed (1).
sgtl5000_1.surroundSoundEnable();
sgtl5000_1.surroundSound(7, 3); // Configures virtual surround width from 0 (mono) to 7 (widest). select may be set to 1 (disable), 2 (mono input) or 3 (stereo input).
sgtl5000_1.autoVolumeEnable();
sgtl5000_1.autoVolumeControl(1, 1, 1, 0.9, 0.01, 0.05);
sgtl5000_1.eqSelect(GRAPHIC_EQUALIZER);
sgtl5000_1.eqBands(EQ_BASS_DEFAULT, EQ_MIDBASS_DEFAULT, EQ_MID_DEFAULT, EQ_MIDTREBLE_DEFAULT, EQ_TREBLE_DEFAULT);
sgtl5000.audioPostProcessorEnable();
sgtl5000.enhanceBassEnable();
sgtl5000.enhanceBass(1.0, 1.5, 0, 5); // enhanceBass(1.0, 1.0, 1, 2); // Configures the bass enhancement by setting the levels of the original stereo signal and the bass-enhanced mono level which will be mixed together. The high-pass filter may be enabled (0) or bypassed (1).
sgtl5000.surroundSoundEnable();
sgtl5000.surroundSound(7, 3); // Configures virtual surround width from 0 (mono) to 7 (widest). select may be set to 1 (disable), 2 (mono input) or 3 (stereo input).
sgtl5000.autoVolumeEnable();
sgtl5000.autoVolumeControl(1, 1, 1, 0.9, 0.01, 0.05);
#else
sgtl5000_1.audioProcessorDisable();
sgtl5000_1.autoVolumeDisable();
sgtl5000_1.surroundSoundDisable();
sgtl5000_1.enhanceBassDisable();
sgtl5000.audioProcessorDisable();
sgtl5000.autoVolumeDisable();
sgtl5000.surroundSoundDisable();
sgtl5000.enhanceBassDisable();
#endif
#ifdef DEBUG
Serial.println(F("Teensy-Audio-Board enabled."));
@ -2203,13 +2205,13 @@ void set_fx_params(void)
#endif
#ifdef SGTL5000_AUDIO_ENHANCE
sgtl5000_1.eqBands(
mapfloat(configuration.fx.eq_bass, EQ_BASS_MIN, EQ_BASS_MAX, -1.0, 1.0),
mapfloat(configuration.fx.eq_midbass, EQ_MIDBASS_MIN, EQ_MIDBASS_MAX, -1.0, 1.0),
mapfloat(configuration.fx.eq_mid, EQ_MID_MIN, EQ_MID_MAX, -1.0, 1.0),
mapfloat(configuration.fx.eq_midtreble, EQ_MIDTREBLE_MIN, EQ_MIDTREBLE_MAX, -1.0, 1.0),
mapfloat(configuration.fx.eq_treble, EQ_TREBLE_MIN, EQ_TREBLE_MAX, -1.0, 1.0)
);
sgtl5000.setEQFc(1, mapfloat(configuration.fx.eq_1, EQ_1_MIN, EQ_1_MAX, -1.0, 1.0));
sgtl5000.setEQFc(2, mapfloat(configuration.fx.eq_2, EQ_2_MIN, EQ_2_MAX, -1.0, 1.0));
sgtl5000.setEQFc(3, mapfloat(configuration.fx.eq_3, EQ_3_MIN, EQ_3_MAX, -1.0, 1.0));
sgtl5000.setEQFc(4, mapfloat(configuration.fx.eq_4, EQ_4_MIN, EQ_4_MAX, -1.0, 1.0));
sgtl5000.setEQFc(5, mapfloat(configuration.fx.eq_5, EQ_5_MIN, EQ_5_MAX, -1.0, 1.0));
sgtl5000.setEQFc(6, mapfloat(configuration.fx.eq_6, EQ_6_MIN, EQ_6_MAX, -1.0, 1.0));
sgtl5000.setEQFc(7, mapfloat(configuration.fx.eq_7, EQ_7_MIN, EQ_7_MAX, -1.0, 1.0));
#endif
init_MIDI_send_CC();

187
UI.hpp

@ -26,9 +26,11 @@
#ifndef _UI_HPP_
#define _UI_HPP_
#include <LCDMenuLib2.h>
#include <MD_REncoder.h>
#include "config.h"
#include "disp_plus.h"
#include "synth_dexed.h"
#include "effect_modulated_delay.h"
#include "effect_stereo_mono.h"
#ifdef USE_PLATEREVERB
@ -36,10 +38,6 @@
#else
#include "effect_freeverbf.h"
#endif
#include "synth_dexed.h"
#include <LCDMenuLib2.h>
#include <MD_REncoder.h>
#define _LCDML_DISP_cols LCD_cols
#define _LCDML_DISP_rows LCD_rows
@ -113,8 +111,13 @@ extern float drums_volume;
extern void change_disp_sd(bool d);
#endif
extern AudioControlSGTL5000 sgtl5000_1;
extern AudioSynthDexed* MicroDexed[NUM_DEXED];
#ifdef SGTL5000_AUDIO_ENHANCE
#include "control_sgtl5000plus.h"
extern AudioControlSGTL5000Plus sgtl5000;
#else
extern AudioControlSGTL5000 sgtl5000;
#endif
#if defined(USE_FX)
extern AudioSynthWaveform* chorus_modulator[NUM_DEXED];
extern AudioEffectModulatedDelay* modchorus[NUM_DEXED];
@ -314,11 +317,13 @@ void UI_func_voice_select(uint8_t param);
void UI_func_sysex_send_voice(uint8_t param);
void UI_func_sysex_receive_bank(uint8_t param);
void UI_func_sysex_send_bank(uint8_t param);
void UI_func_eq_bass(uint8_t param);
void UI_func_eq_midbass(uint8_t param);
void UI_func_eq_mid(uint8_t param);
void UI_func_eq_midtreble(uint8_t param);
void UI_func_eq_treble(uint8_t param);
void UI_func_eq_1(uint8_t param);
void UI_func_eq_2(uint8_t param);
void UI_func_eq_3(uint8_t param);
void UI_func_eq_4(uint8_t param);
void UI_func_eq_5(uint8_t param);
void UI_func_eq_6(uint8_t param);
void UI_func_eq_7(uint8_t param);
void UI_function_not_enabled(void);
void UI_function_not_implemented(uint8_t param);
void UI_func_favorites(uint8_t param);
@ -7638,14 +7643,102 @@ void UI_func_sysex_send_voice(uint8_t param)
}
}
void UI_func_eq_bass(uint8_t param)
void UI_func_eq_1(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ 50Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
#else
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd_special_chars(METERBAR);
}
if (LCDML.FUNC_loop()) // ****** LOOP *********
{
if ((LCDML.BT_checkDown() && encoderDir[ENC_R].Down()) || (LCDML.BT_checkUp() && encoderDir[ENC_R].Up()))
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_1 = constrain(configuration.fx.eq_1 + ENCODER[ENC_R].speed(), EQ_1_MIN, EQ_1_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_1 = constrain(configuration.fx.eq_1 - ENCODER[ENC_R].speed(), EQ_1_MIN, EQ_1_MAX);
}
}
lcd_display_meter_float("EQ 50Hz", configuration.fx.eq_1, 0.1, 0.0, EQ_1_MIN, EQ_1_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(1, mapfloat(configuration.fx.eq_1, EQ_1_MIN, EQ_1_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_1), configuration.fx.eq_1);
}
#endif
}
void UI_func_eq_2(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ 120Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
#else
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd_special_chars(METERBAR);
}
if (LCDML.FUNC_loop()) // ****** LOOP *********
{
if ((LCDML.BT_checkDown() && encoderDir[ENC_R].Down()) || (LCDML.BT_checkUp() && encoderDir[ENC_R].Up()))
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_2 = constrain(configuration.fx.eq_2 + ENCODER[ENC_R].speed(), EQ_2_MIN, EQ_2_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_2 = constrain(configuration.fx.eq_2 - ENCODER[ENC_R].speed(), EQ_2_MIN, EQ_2_MAX);
}
}
lcd_display_meter_float("EQ 120Hz", configuration.fx.eq_2, 0.1, 0.0, EQ_2_MIN, EQ_2_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(2, mapfloat(configuration.fx.eq_2, EQ_2_MIN, EQ_2_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_2), configuration.fx.eq_2);
}
#endif
}
void UI_func_eq_3(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ Bass"));
lcd.print(F("EQ 220Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
@ -7662,34 +7755,34 @@ void UI_func_eq_bass(uint8_t param)
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_bass = constrain(configuration.fx.eq_bass + ENCODER[ENC_R].speed(), EQ_BASS_MIN, EQ_BASS_MAX);
configuration.fx.eq_3 = constrain(configuration.fx.eq_3 + ENCODER[ENC_R].speed(), EQ_3_MIN, EQ_3_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_bass = constrain(configuration.fx.eq_bass - ENCODER[ENC_R].speed(), EQ_BASS_MIN, EQ_BASS_MAX);
configuration.fx.eq_3 = constrain(configuration.fx.eq_3 - ENCODER[ENC_R].speed(), EQ_3_MIN, EQ_3_MAX);
}
}
lcd_display_meter_float("EQ Bass", configuration.fx.eq_bass, 0.1, 0.0, EQ_BASS_MIN, EQ_BASS_MAX, 1, 1, false, true, true);
sgtl5000_1.eqBand(0, mapfloat(configuration.fx.eq_bass, EQ_BASS_MIN, EQ_BASS_MAX, -1.0, 1.0));
lcd_display_meter_float("EQ 220Hz", configuration.fx.eq_3, 0.1, 0.0, EQ_3_MIN, EQ_3_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(3, mapfloat(configuration.fx.eq_3, EQ_3_MIN, EQ_3_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_bass), configuration.fx.eq_bass);
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_3), configuration.fx.eq_3);
}
#endif
}
void UI_func_eq_midbass(uint8_t param)
void UI_func_eq_4(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ MidBass"));
lcd.print(F("EQ 1000Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
@ -7706,34 +7799,34 @@ void UI_func_eq_midbass(uint8_t param)
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_midbass = constrain(configuration.fx.eq_midbass + ENCODER[ENC_R].speed(), EQ_MIDBASS_MIN, EQ_MIDBASS_MAX);
configuration.fx.eq_4 = constrain(configuration.fx.eq_4 + ENCODER[ENC_R].speed(), EQ_4_MIN, EQ_4_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_midbass = constrain(configuration.fx.eq_midbass - ENCODER[ENC_R].speed(), EQ_MIDBASS_MIN, EQ_MIDBASS_MAX);
configuration.fx.eq_4 = constrain(configuration.fx.eq_4 - ENCODER[ENC_R].speed(), EQ_4_MIN, EQ_4_MAX);
}
}
lcd_display_meter_float("EQ MidBass", configuration.fx.eq_midbass, 0.1, 0.0, EQ_MIDBASS_MIN, EQ_MIDBASS_MAX, 1, 1, false, true, true);
sgtl5000_1.eqBand(1, mapfloat(configuration.fx.eq_midbass, EQ_MIDBASS_MIN, EQ_MIDBASS_MAX, -1.0, 1.0));
lcd_display_meter_float("EQ 1000Hz", configuration.fx.eq_4, 0.1, 0.0, EQ_4_MIN, EQ_4_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(4, mapfloat(configuration.fx.eq_4, EQ_4_MIN, EQ_4_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_midbass), configuration.fx.eq_midbass);
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_4), configuration.fx.eq_4);
}
#endif
}
void UI_func_eq_mid(uint8_t param)
void UI_func_eq_5(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ Mid"));
lcd.print(F("EQ 2000Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
@ -7750,34 +7843,34 @@ void UI_func_eq_mid(uint8_t param)
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_mid = constrain(configuration.fx.eq_mid + ENCODER[ENC_R].speed(), EQ_MID_MIN, EQ_MID_MAX);
configuration.fx.eq_5 = constrain(configuration.fx.eq_5 + ENCODER[ENC_R].speed(), EQ_5_MIN, EQ_5_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_mid = constrain(configuration.fx.eq_mid - ENCODER[ENC_R].speed(), EQ_MID_MIN, EQ_MID_MAX);
configuration.fx.eq_5 = constrain(configuration.fx.eq_5 - ENCODER[ENC_R].speed(), EQ_5_MIN, EQ_5_MAX);
}
}
lcd_display_meter_float("EQ Mid", configuration.fx.eq_mid, 0.1, 0.0, EQ_MID_MIN, EQ_MID_MAX, 1, 1, false, true, true);
sgtl5000_1.eqBand(2, mapfloat(configuration.fx.eq_mid, EQ_MID_MIN, EQ_MID_MAX, -1.0, 1.0));
lcd_display_meter_float("EQ 2000Hz", configuration.fx.eq_5, 0.1, 0.0, EQ_5_MIN, EQ_5_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(5, mapfloat(configuration.fx.eq_5, EQ_5_MIN, EQ_5_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_mid), configuration.fx.eq_mid);
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_5), configuration.fx.eq_5);
}
#endif
}
void UI_func_eq_midtreble(uint8_t param)
void UI_func_eq_6(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ MidTreble"));
lcd.print(F("EQ 7000Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
@ -7794,34 +7887,34 @@ void UI_func_eq_midtreble(uint8_t param)
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_midtreble = constrain(configuration.fx.eq_midtreble + ENCODER[ENC_R].speed(), EQ_MIDTREBLE_MIN, EQ_MIDTREBLE_MAX);
configuration.fx.eq_6 = constrain(configuration.fx.eq_6 + ENCODER[ENC_R].speed(), EQ_6_MIN, EQ_6_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_midtreble = constrain(configuration.fx.eq_midtreble - ENCODER[ENC_R].speed(), EQ_MIDTREBLE_MIN, EQ_MIDTREBLE_MAX);
configuration.fx.eq_6 = constrain(configuration.fx.eq_6 - ENCODER[ENC_R].speed(), EQ_6_MIN, EQ_6_MAX);
}
}
lcd_display_meter_float("EQ MidTreble", configuration.fx.eq_midtreble, 0.1, 0.0, EQ_MIDTREBLE_MIN, EQ_MIDTREBLE_MAX, 1, 1, false, true, true);
sgtl5000_1.eqBand(3, mapfloat(configuration.fx.eq_midtreble, EQ_MIDTREBLE_MIN, EQ_MIDTREBLE_MAX, -1.0, 1.0));
lcd_display_meter_float("EQ 7000Hz", configuration.fx.eq_6, 0.1, 0.0, EQ_6_MIN, EQ_6_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(6, mapfloat(configuration.fx.eq_6, EQ_6_MIN, EQ_6_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_midtreble), configuration.fx.eq_midtreble);
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_6), configuration.fx.eq_6);
}
#endif
}
void UI_func_eq_treble(uint8_t param)
void UI_func_eq_7(uint8_t param)
{
#ifndef SGTL5000_AUDIO_ENHANCE
if (LCDML.FUNC_setup()) // ****** SETUP *********
{
encoderDir[ENC_R].reset();
lcd.setCursor(0, 0);
lcd.print(F("EQ Treble"));
lcd.print(F("EQ 10000Hz"));
lcd.setCursor(0, 1);
lcd.print(F("Not implemented."));
}
@ -7838,22 +7931,22 @@ void UI_func_eq_treble(uint8_t param)
{
if (LCDML.BT_checkDown())
{
configuration.fx.eq_treble = constrain(configuration.fx.eq_treble + ENCODER[ENC_R].speed(), EQ_TREBLE_MIN, EQ_TREBLE_MAX);
configuration.fx.eq_7 = constrain(configuration.fx.eq_7 + ENCODER[ENC_R].speed(), EQ_7_MIN, EQ_7_MAX);
}
else if (LCDML.BT_checkUp())
{
configuration.fx.eq_treble = constrain(configuration.fx.eq_treble - ENCODER[ENC_R].speed(), EQ_TREBLE_MIN, EQ_TREBLE_MAX);
configuration.fx.eq_7 = constrain(configuration.fx.eq_7 - ENCODER[ENC_R].speed(), EQ_7_MIN, EQ_7_MAX);
}
}
lcd_display_meter_float("EQ Treble", configuration.fx.eq_treble, 0.1, 0.0, EQ_TREBLE_MIN, EQ_TREBLE_MAX, 1, 1, false, true, true);
sgtl5000_1.eqBand(4, mapfloat(configuration.fx.eq_treble, EQ_TREBLE_MIN, EQ_TREBLE_MAX, -1.0, 1.0));
lcd_display_meter_float("EQ 10000Hz", configuration.fx.eq_7, 0.1, 0.0, EQ_7_MIN, EQ_7_MAX, 1, 1, false, true, true);
sgtl5000.setEQFc(7, mapfloat(configuration.fx.eq_7, EQ_7_MIN, EQ_7_MAX, -1.0, 1.0));
}
if (LCDML.FUNC_close()) // ****** STABLE END *********
{
lcd_special_chars(SCROLLBAR);
encoderDir[ENC_R].reset();
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_treble), configuration.fx.eq_treble);
EEPROM.update(EEPROM_START_ADDRESS + offsetof(configuration_s, fx.eq_7), configuration.fx.eq_7);
}
#endif
}

@ -54,91 +54,93 @@ LCDML_add(20, LCDML_0_1_2_3_4, 2, "Damping", UI_func_reverb_damping);
LCDML_add(21, LCDML_0_1_2_3_4, 3, "Level", UI_func_reverb_level);
LCDML_add(22, LCDML_0_1_2_3_4, 4, "Reverb Send", UI_func_reverb_send);
LCDML_add(23, LCDML_0_1_2_3, 5, "EQ", NULL);
LCDML_add(24, LCDML_0_1_2_3_5, 1, "Bass", UI_func_eq_bass);
LCDML_add(25, LCDML_0_1_2_3_5, 2, "MidBass", UI_func_eq_midbass);
LCDML_add(26, LCDML_0_1_2_3_5, 3, "Mid", UI_func_eq_mid);
LCDML_add(27, LCDML_0_1_2_3_5, 4, "MidTreble", UI_func_eq_midtreble);
LCDML_add(28, LCDML_0_1_2_3_5, 5, "Treble", UI_func_eq_treble);
LCDML_add(29, LCDML_0_1, 3, "Controller", NULL);
LCDML_add(30, LCDML_0_1_3, 1, "Pitchbend", NULL);
LCDML_add(31, LCDML_0_1_3_1, 1, "PB Range", UI_func_pb_range);
LCDML_add(32, LCDML_0_1_3_1, 2, "PB Step", UI_func_pb_step);
LCDML_add(33, LCDML_0_1_3, 2, "Mod Wheel", NULL);
LCDML_add(34, LCDML_0_1_3_2, 1, "MW Range", UI_func_mw_range);
LCDML_add(35, LCDML_0_1_3_2, 2, "MW Assign", UI_func_mw_assign);
LCDML_add(36, LCDML_0_1_3_2, 3, "MW Mode", UI_func_mw_mode);
LCDML_add(37, LCDML_0_1_3, 3, "Aftertouch", NULL);
LCDML_add(38, LCDML_0_1_3_3, 1, "AT Range", UI_func_at_range);
LCDML_add(39, LCDML_0_1_3_3, 2, "AT Assign", UI_func_at_assign);
LCDML_add(40, LCDML_0_1_3_3, 3, "AT Mode", UI_func_at_mode);
LCDML_add(41, LCDML_0_1_3, 4, "Foot Ctrl", NULL);
LCDML_add(42, LCDML_0_1_3_4, 1, "FC Range", UI_func_fc_range);
LCDML_add(43, LCDML_0_1_3_4, 2, "FC Assign", UI_func_fc_assign);
LCDML_add(44, LCDML_0_1_3_4, 3, "FC Mode", UI_func_fc_mode);
LCDML_add(45, LCDML_0_1_3, 5, "Breath Ctrl", NULL);
LCDML_add(46, LCDML_0_1_3_5, 1, "BC Range", UI_func_bc_range);
LCDML_add(47, LCDML_0_1_3_5, 2, "BC Assign", UI_func_bc_assign);
LCDML_add(48, LCDML_0_1_3_5, 3, "BC Mode", UI_func_bc_mode);
LCDML_add(49, LCDML_0_1, 4, "MIDI", NULL);
LCDML_add(50, LCDML_0_1_4, 1, "MIDI Channel", UI_func_midi_channel);
LCDML_add(51, LCDML_0_1_4, 2, "Lowest Note", UI_func_lowest_note);
LCDML_add(52, LCDML_0_1_4, 3, "Highest Note", UI_func_highest_note);
LCDML_add(53, LCDML_0_1_4, 4, "MIDI Send Voice", UI_func_sysex_send_voice);
LCDML_add(54, LCDML_0_1, 5, "Setup", NULL);
LCDML_add(55, LCDML_0_1_5, 1, "Portamento", NULL);
LCDML_add(56, LCDML_0_1_5_1, 1, "Port. Mode", UI_func_portamento_mode);
LCDML_add(57, LCDML_0_1_5_1, 2, "Port. Gliss", UI_func_portamento_glissando);
LCDML_add(58, LCDML_0_1_5_1, 3, "Port. Time", UI_func_portamento_time);
LCDML_add(59, LCDML_0_1_5, 2, "Polyphony", UI_func_polyphony);
LCDML_add(60, LCDML_0_1_5, 3, "Transpose", UI_func_transpose);
LCDML_add(61, LCDML_0_1_5, 4, "Fine Tune", UI_func_tune);
LCDML_add(62, LCDML_0_1_5, 5, "Mono/Poly", UI_func_mono_poly);
LCDML_add(63, LCDML_0_1, 6, "Internal", NULL);
LCDML_add(64, LCDML_0_1_6, 1, "Note Refresh", UI_func_note_refresh);
LCDML_add(65, LCDML_0_1_6, 2, "Velocity Lvl", UI_func_velocity_level);
LCDML_add(66, LCDML_0_1, 7, "Operator", UI_handle_OP);
LCDML_add(67, LCDML_0_1, 8, "Save Voice", UI_func_save_voice);
LCDML_add(68, LCDML_0, 3, "Load/Save", NULL);
LCDML_add(69, LCDML_0_3, 1, "Performance", NULL);
LCDML_add(70, LCDML_0_3_1, 1, "Load Perf.", UI_func_load_performance);
LCDML_add(71, LCDML_0_3_1, 2, "Save Perf.", UI_func_save_performance);
LCDML_add(72, LCDML_0_3, 2, "Voice Config", NULL);
LCDML_add(73, LCDML_0_3_2, 1, "Load Voice Cfg", UI_func_load_voiceconfig);
LCDML_add(74, LCDML_0_3_2, 2, "Save Voice Cfg", UI_func_save_voiceconfig);
LCDML_add(75, LCDML_0_3, 3, "Effects", NULL);
LCDML_add(76, LCDML_0_3_3, 1, "Load Effects", UI_func_load_fx);
LCDML_add(77, LCDML_0_3_3, 2, "Save Effects", UI_func_save_fx);
LCDML_add(78, LCDML_0_3, 5, "MIDI", NULL);
LCDML_add(79, LCDML_0_3_5, 1, "MIDI Recv Bank", UI_func_sysex_receive_bank);
LCDML_add(80, LCDML_0_3_5, 2, "MIDI Snd Bank", UI_func_sysex_send_bank);
LCDML_add(81, LCDML_0_3_5, 3, "MIDI Snd Voice", UI_func_sysex_send_voice);
LCDML_add(82, LCDML_0, 4, "Drums", NULL);
LCDML_add(83, LCDML_0_4, 1, "Drums Main Vol", UI_func_drum_main_volume);
LCDML_add(84, LCDML_0_4, 2, "Drum Volumes", UI_func_drum_volume);
LCDML_add(85, LCDML_0_4, 3, "Drum Pan", UI_func_drum_pan);
LCDML_add(86, LCDML_0_4, 4, "Drum Rev.Send", UI_func_drum_reverb_send);
LCDML_add(87, LCDML_0, 5, "Sequencer", NULL);
LCDML_add(88, LCDML_0_5, 1, "Sequencer", UI_func_sequencer);
LCDML_add(89, LCDML_0_5, 2, "Vel./Chrd Edit", UI_func_seq_vel_editor);
LCDML_add(90, LCDML_0_5, 3, "Pattern Chain", UI_func_seq_pat_chain);
LCDML_add(91, LCDML_0_5, 4, "Arpeggio", UI_func_arpeggio);
LCDML_add(92, LCDML_0_5, 5, "Seq. Settings", NULL);
LCDML_add(93, LCDML_0_5_5, 1, "Tempo", UI_func_seq_tempo);
LCDML_add(94, LCDML_0_5_5, 2, "Seq. Length", UI_func_seq_lenght);
LCDML_add(95, LCDML_0_5_5, 3, "Track Setup", UI_func_seq_track_setup);
LCDML_add(96, LCDML_0_5_5, 4, "Seq.Disp.Style", UI_func_seq_display_style);
LCDML_add(97, LCDML_0_5_5, 5, "dexed assign", UI_func_dexed_assign);
LCDML_add(98, LCDML_0_5_5, 6, "shift&transp.", UI_func_arp_shift);
LCDML_add(99, LCDML_0_5_5, 8, "ChordTrack Keys", UI_func_seq_chord_keys_ammount);
LCDML_add(100, LCDML_0_5_5, 6, "L.Transp.Key", UI_func_seq_live_transpose_oct);
LCDML_add(101, LCDML_0_5, 6, "LOAD Seq.Data", UI_func_seq_state_load);
LCDML_add(102, LCDML_0_5, 7, "SAVE Seq.Data", UI_func_seq_state_save);
LCDML_add(103, LCDML_0, 6, "System", NULL);
LCDML_add(104, LCDML_0_6, 1, "Stereo/Mono", UI_func_stereo_mono);
LCDML_add(105, LCDML_0_6, 2, "MIDI Soft THRU", UI_func_midi_soft_thru);
LCDML_add(106, LCDML_0_6, 3, "Favorites", UI_func_favorites);
LCDML_add(107, LCDML_0_6, 4, "EEPROM Reset", UI_func_eeprom_reset);
LCDML_add(108, LCDML_0, 7, "Info", UI_func_information);
LCDML_addAdvanced(109, LCDML_0, 8, COND_hide, "Volume", UI_func_volume, 0, _LCDML_TYPE_default);
#define _LCDML_DISP_cnt 109
LCDML_add(24, LCDML_0_1_2_3_5, 1, "50Hz", UI_func_eq_1);
LCDML_add(25, LCDML_0_1_2_3_5, 2, "120Hz", UI_func_eq_2);
LCDML_add(26, LCDML_0_1_2_3_5, 3, "220Hz", UI_func_eq_3);
LCDML_add(27, LCDML_0_1_2_3_5, 4, "1000Hz", UI_func_eq_4);
LCDML_add(28, LCDML_0_1_2_3_5, 5, "2000Hz", UI_func_eq_5);
LCDML_add(29, LCDML_0_1_2_3_5, 6, "7000Hz", UI_func_eq_6);
LCDML_add(30, LCDML_0_1_2_3_5, 7, "10000Hz", UI_func_eq_7);
LCDML_add(30, LCDML_0_1, 3, "Controller", NULL);
LCDML_add(31, LCDML_0_1_3, 1, "Pitchbend", NULL);
LCDML_add(32, LCDML_0_1_3_1, 1, "PB Range", UI_func_pb_range);
LCDML_add(33, LCDML_0_1_3_1, 2, "PB Step", UI_func_pb_step);
LCDML_add(34, LCDML_0_1_3, 2, "Mod Wheel", NULL);
LCDML_add(35, LCDML_0_1_3_2, 1, "MW Range", UI_func_mw_range);
LCDML_add(36, LCDML_0_1_3_2, 2, "MW Assign", UI_func_mw_assign);
LCDML_add(37, LCDML_0_1_3_2, 3, "MW Mode", UI_func_mw_mode);
LCDML_add(38, LCDML_0_1_3, 3, "Aftertouch", NULL);
LCDML_add(39, LCDML_0_1_3_3, 1, "AT Range", UI_func_at_range);
LCDML_add(40, LCDML_0_1_3_3, 2, "AT Assign", UI_func_at_assign);
LCDML_add(41, LCDML_0_1_3_3, 3, "AT Mode", UI_func_at_mode);
LCDML_add(42, LCDML_0_1_3, 4, "Foot Ctrl", NULL);
LCDML_add(43, LCDML_0_1_3_4, 1, "FC Range", UI_func_fc_range);
LCDML_add(44, LCDML_0_1_3_4, 2, "FC Assign", UI_func_fc_assign);
LCDML_add(45, LCDML_0_1_3_4, 3, "FC Mode", UI_func_fc_mode);
LCDML_add(46, LCDML_0_1_3, 5, "Breath Ctrl", NULL);
LCDML_add(47, LCDML_0_1_3_5, 1, "BC Range", UI_func_bc_range);
LCDML_add(48, LCDML_0_1_3_5, 2, "BC Assign", UI_func_bc_assign);
LCDML_add(49, LCDML_0_1_3_5, 3, "BC Mode", UI_func_bc_mode);
LCDML_add(50, LCDML_0_1, 4, "MIDI", NULL);
LCDML_add(51, LCDML_0_1_4, 1, "MIDI Channel", UI_func_midi_channel);
LCDML_add(52, LCDML_0_1_4, 2, "Lowest Note", UI_func_lowest_note);
LCDML_add(53, LCDML_0_1_4, 3, "Highest Note", UI_func_highest_note);
LCDML_add(54, LCDML_0_1_4, 4, "MIDI Send Voice", UI_func_sysex_send_voice);
LCDML_add(55, LCDML_0_1, 5, "Setup", NULL);
LCDML_add(56, LCDML_0_1_5, 1, "Portamento", NULL);
LCDML_add(57, LCDML_0_1_5_1, 1, "Port. Mode", UI_func_portamento_mode);
LCDML_add(58, LCDML_0_1_5_1, 2, "Port. Gliss", UI_func_portamento_glissando);
LCDML_add(59, LCDML_0_1_5_1, 3, "Port. Time", UI_func_portamento_time);
LCDML_add(60, LCDML_0_1_5, 2, "Polyphony", UI_func_polyphony);
LCDML_add(61, LCDML_0_1_5, 3, "Transpose", UI_func_transpose);
LCDML_add(62, LCDML_0_1_5, 4, "Fine Tune", UI_func_tune);
LCDML_add(63, LCDML_0_1_5, 5, "Mono/Poly", UI_func_mono_poly);
LCDML_add(64, LCDML_0_1, 6, "Internal", NULL);
LCDML_add(65, LCDML_0_1_6, 1, "Note Refresh", UI_func_note_refresh);
LCDML_add(66, LCDML_0_1_6, 2, "Velocity Lvl", UI_func_velocity_level);
LCDML_add(67, LCDML_0_1, 7, "Operator", UI_handle_OP);
LCDML_add(68, LCDML_0_1, 8, "Save Voice", UI_func_save_voice);
LCDML_add(69, LCDML_0, 3, "Load/Save", NULL);
LCDML_add(70, LCDML_0_3, 1, "Performance", NULL);
LCDML_add(71, LCDML_0_3_1, 1, "Load Perf.", UI_func_load_performance);
LCDML_add(72, LCDML_0_3_1, 2, "Save Perf.", UI_func_save_performance);
LCDML_add(73, LCDML_0_3, 2, "Voice Config", NULL);
LCDML_add(74, LCDML_0_3_2, 1, "Load Voice Cfg", UI_func_load_voiceconfig);
LCDML_add(75, LCDML_0_3_2, 2, "Save Voice Cfg", UI_func_save_voiceconfig);
LCDML_add(76, LCDML_0_3, 3, "Effects", NULL);
LCDML_add(77, LCDML_0_3_3, 1, "Load Effects", UI_func_load_fx);
LCDML_add(78, LCDML_0_3_3, 2, "Save Effects", UI_func_save_fx);
LCDML_add(79, LCDML_0_3, 5, "MIDI", NULL);
LCDML_add(80, LCDML_0_3_5, 1, "MIDI Recv Bank", UI_func_sysex_receive_bank);
LCDML_add(81, LCDML_0_3_5, 2, "MIDI Snd Bank", UI_func_sysex_send_bank);
LCDML_add(82, LCDML_0_3_5, 3, "MIDI Snd Voice", UI_func_sysex_send_voice);
LCDML_add(83, LCDML_0, 4, "Drums", NULL);
LCDML_add(84, LCDML_0_4, 1, "Drums Main Vol", UI_func_drum_main_volume);
LCDML_add(85, LCDML_0_4, 2, "Drum Volumes", UI_func_drum_volume);
LCDML_add(86, LCDML_0_4, 3, "Drum Pan", UI_func_drum_pan);
LCDML_add(87, LCDML_0_4, 4, "Drum Rev.Send", UI_func_drum_reverb_send);
LCDML_add(88, LCDML_0, 5, "Sequencer", NULL);
LCDML_add(89, LCDML_0_5, 1, "Sequencer", UI_func_sequencer);
LCDML_add(90, LCDML_0_5, 2, "Vel./Chrd Edit", UI_func_seq_vel_editor);
LCDML_add(91, LCDML_0_5, 3, "Pattern Chain", UI_func_seq_pat_chain);
LCDML_add(92, LCDML_0_5, 4, "Arpeggio", UI_func_arpeggio);
LCDML_add(93, LCDML_0_5, 5, "Seq. Settings", NULL);
LCDML_add(94, LCDML_0_5_5, 1, "Tempo", UI_func_seq_tempo);
LCDML_add(95, LCDML_0_5_5, 2, "Seq. Length", UI_func_seq_lenght);
LCDML_add(96, LCDML_0_5_5, 3, "Track Setup", UI_func_seq_track_setup);
LCDML_add(97, LCDML_0_5_5, 4, "Seq.Disp.Style", UI_func_seq_display_style);
LCDML_add(98, LCDML_0_5_5, 5, "dexed assign", UI_func_dexed_assign);
LCDML_add(99, LCDML_0_5_5, 6, "shift&transp.", UI_func_arp_shift);
LCDML_add(100, LCDML_0_5_5, 8, "ChordTrack Keys", UI_func_seq_chord_keys_ammount);
LCDML_add(101, LCDML_0_5_5, 6, "L.Transp.Key", UI_func_seq_live_transpose_oct);
LCDML_add(102, LCDML_0_5, 6, "LOAD Seq.Data", UI_func_seq_state_load);
LCDML_add(103, LCDML_0_5, 7, "SAVE Seq.Data", UI_func_seq_state_save);
LCDML_add(104, LCDML_0, 6, "System", NULL);
LCDML_add(105, LCDML_0_6, 1, "Stereo/Mono", UI_func_stereo_mono);
LCDML_add(106, LCDML_0_6, 2, "MIDI Soft THRU", UI_func_midi_soft_thru);
LCDML_add(107, LCDML_0_6, 3, "Favorites", UI_func_favorites);
LCDML_add(108, LCDML_0_6, 4, "EEPROM Reset", UI_func_eeprom_reset);
LCDML_add(109, LCDML_0, 7, "Info", UI_func_information);
LCDML_addAdvanced(110, LCDML_0, 8, COND_hide, "Volume", UI_func_volume, 0, _LCDML_TYPE_default);
#define _LCDML_DISP_cnt 110
#endif

@ -57,91 +57,93 @@ LCDML_add(23, LCDML_0_1_2_3_4, 5, "Diffusion", UI_func_reverb_diffusion);
LCDML_add(24, LCDML_0_1_2_3_4, 6, "Level", UI_func_reverb_level);
LCDML_add(25, LCDML_0_1_2_3_4, 7, "Reverb Send", UI_func_reverb_send);
LCDML_add(26, LCDML_0_1_2_3, 5, "EQ", NULL);
LCDML_add(27, LCDML_0_1_2_3_5, 1, "Bass", UI_func_eq_bass);
LCDML_add(28, LCDML_0_1_2_3_5, 2, "MidBass", UI_func_eq_midbass);
LCDML_add(29, LCDML_0_1_2_3_5, 3, "Mid", UI_func_eq_mid);
LCDML_add(30, LCDML_0_1_2_3_5, 4, "MidTreble", UI_func_eq_midtreble);
LCDML_add(31, LCDML_0_1_2_3_5, 5, "Treble", UI_func_eq_treble);
LCDML_add(32, LCDML_0_1, 3, "Controller", NULL);
LCDML_add(33, LCDML_0_1_3, 1, "Pitchbend", NULL);
LCDML_add(34, LCDML_0_1_3_1, 1, "PB Range", UI_func_pb_range);
LCDML_add(35, LCDML_0_1_3_1, 2, "PB Step", UI_func_pb_step);
LCDML_add(36, LCDML_0_1_3, 2, "Mod Wheel", NULL);
LCDML_add(37, LCDML_0_1_3_2, 1, "MW Range", UI_func_mw_range);
LCDML_add(38, LCDML_0_1_3_2, 2, "MW Assign", UI_func_mw_assign);
LCDML_add(39, LCDML_0_1_3_2, 3, "MW Mode", UI_func_mw_mode);
LCDML_add(40, LCDML_0_1_3, 3, "Aftertouch", NULL);
LCDML_add(41, LCDML_0_1_3_3, 1, "AT Range", UI_func_at_range);
LCDML_add(42, LCDML_0_1_3_3, 2, "AT Assign", UI_func_at_assign);
LCDML_add(43, LCDML_0_1_3_3, 3, "AT Mode", UI_func_at_mode);
LCDML_add(44, LCDML_0_1_3, 4, "Foot Ctrl", NULL);
LCDML_add(45, LCDML_0_1_3_4, 1, "FC Range", UI_func_fc_range);
LCDML_add(46, LCDML_0_1_3_4, 2, "FC Assign", UI_func_fc_assign);
LCDML_add(47, LCDML_0_1_3_4, 3, "FC Mode", UI_func_fc_mode);
LCDML_add(48, LCDML_0_1_3, 5, "Breath Ctrl", NULL);
LCDML_add(49, LCDML_0_1_3_5, 1, "BC Range", UI_func_bc_range);
LCDML_add(50, LCDML_0_1_3_5, 2, "BC Assign", UI_func_bc_assign);
LCDML_add(51, LCDML_0_1_3_5, 3, "BC Mode", UI_func_bc_mode);
LCDML_add(52, LCDML_0_1, 4, "MIDI", NULL);
LCDML_add(53, LCDML_0_1_4, 1, "MIDI Channel", UI_func_midi_channel);
LCDML_add(54, LCDML_0_1_4, 2, "Lowest Note", UI_func_lowest_note);
LCDML_add(55, LCDML_0_1_4, 3, "Highest Note", UI_func_highest_note);
LCDML_add(56, LCDML_0_1_4, 4, "MIDI Send Voice", UI_func_sysex_send_voice);
LCDML_add(57, LCDML_0_1, 5, "Setup", NULL);
LCDML_add(58, LCDML_0_1_5, 1, "Portamento", NULL);
LCDML_add(59, LCDML_0_1_5_1, 1, "Port. Mode", UI_func_portamento_mode);
LCDML_add(60, LCDML_0_1_5_1, 2, "Port. Gliss", UI_func_portamento_glissando);
LCDML_add(61, LCDML_0_1_5_1, 3, "Port. Time", UI_func_portamento_time);
LCDML_add(62, LCDML_0_1_5, 2, "Polyphony", UI_func_polyphony);
LCDML_add(63, LCDML_0_1_5, 3, "Transpose", UI_func_transpose);
LCDML_add(64, LCDML_0_1_5, 4, "Fine Tune", UI_func_tune);
LCDML_add(65, LCDML_0_1_5, 5, "Mono/Poly", UI_func_mono_poly);
LCDML_add(66, LCDML_0_1, 6, "Internal", NULL);
LCDML_add(67, LCDML_0_1_6, 1, "Note Refresh", UI_func_note_refresh);
LCDML_add(68, LCDML_0_1_6, 2, "Velocity Lvl", UI_func_velocity_level);
LCDML_add(69, LCDML_0_1, 7, "Operator", UI_handle_OP);
LCDML_add(70, LCDML_0_1, 8, "Save Voice", UI_func_save_voice);
LCDML_add(71, LCDML_0, 3, "Load/Save", NULL);
LCDML_add(72, LCDML_0_3, 1, "Performance", NULL);
LCDML_add(73, LCDML_0_3_1, 1, "Load Perf.", UI_func_load_performance);
LCDML_add(74, LCDML_0_3_1, 2, "Save Perf.", UI_func_save_performance);
LCDML_add(75, LCDML_0_3, 2, "Voice Config", NULL);
LCDML_add(76, LCDML_0_3_2, 1, "Load Voice Cfg", UI_func_load_voiceconfig);
LCDML_add(77, LCDML_0_3_2, 2, "Save Voice Cfg", UI_func_save_voiceconfig);
LCDML_add(78, LCDML_0_3, 3, "Effects", NULL);
LCDML_add(79, LCDML_0_3_3, 1, "Load Effects", UI_func_load_fx);
LCDML_add(80, LCDML_0_3_3, 2, "Save Effects", UI_func_save_fx);
LCDML_add(81, LCDML_0_3, 5, "MIDI", NULL);
LCDML_add(82, LCDML_0_3_5, 1, "MIDI Recv Bank", UI_func_sysex_receive_bank);
LCDML_add(83, LCDML_0_3_5, 2, "MIDI Snd Bank", UI_func_sysex_send_bank);
LCDML_add(84, LCDML_0_3_5, 3, "MIDI Snd Voice", UI_func_sysex_send_voice);
LCDML_add(85, LCDML_0, 4, "Drums", NULL);
LCDML_add(86, LCDML_0_4, 1, "Drums Main Vol", UI_func_drums_main_volume);
LCDML_add(87, LCDML_0_4, 2, "Drum Volumes", UI_func_drum_volume);
LCDML_add(88, LCDML_0_4, 3, "Drum Pan", UI_func_drum_pan);
LCDML_add(89, LCDML_0_4, 4, "Drum Rev.Send", UI_func_drum_reverb_send);
LCDML_add(90, LCDML_0, 5, "Sequencer", NULL);
LCDML_add(91, LCDML_0_5, 1, "Sequencer", UI_func_sequencer);
LCDML_add(92, LCDML_0_5, 2, "Vel./Chrd Edit", UI_func_seq_vel_editor);
LCDML_add(93, LCDML_0_5, 3, "Pattern Chain", UI_func_seq_pat_chain);
LCDML_add(94, LCDML_0_5, 4, "Arpeggio", UI_func_arpeggio);
LCDML_add(95, LCDML_0_5, 5, "Seq. Settings", NULL);
LCDML_add(96, LCDML_0_5_5, 1, "Tempo", UI_func_seq_tempo);
LCDML_add(97, LCDML_0_5_5, 2, "Seq. Length", UI_func_seq_lenght);
LCDML_add(98, LCDML_0_5_5, 3, "Track Setup", UI_func_seq_track_setup);
LCDML_add(99, LCDML_0_5_5, 4, "Seq.Disp.Style", UI_func_seq_display_style);
LCDML_add(100, LCDML_0_5_5, 5, "dexed assign", UI_func_dexed_assign);
LCDML_add(101, LCDML_0_5_5, 6, "shift&transp.", UI_func_arp_shift);
LCDML_add(102, LCDML_0_5_5, 7, "L.Transp.Key", UI_func_seq_live_transpose_oct);
LCDML_add(103, LCDML_0_5_5, 8, "ChordTrack Keys", UI_func_seq_chord_keys_ammount);
LCDML_add(104, LCDML_0_5, 6, "LOAD Seq.Data", UI_func_seq_state_load);
LCDML_add(105, LCDML_0_5, 7, "SAVE Seq.Data", UI_func_seq_state_save);
LCDML_add(106, LCDML_0, 6, "System", NULL);
LCDML_add(107, LCDML_0_6, 1, "Stereo/Mono", UI_func_stereo_mono);
LCDML_add(108, LCDML_0_6, 2, "MIDI Soft THRU", UI_func_midi_soft_thru);
LCDML_add(109, LCDML_0_6, 3, "Favorites", UI_func_favorites);
LCDML_add(110, LCDML_0_6, 4, "EEPROM Reset", UI_func_eeprom_reset);
LCDML_add(111, LCDML_0, 7, "Info", UI_func_information);
LCDML_addAdvanced(112, LCDML_0, 8, COND_hide, "Volume", UI_func_volume, 0, _LCDML_TYPE_default);
#define _LCDML_DISP_cnt 112
LCDML_add(27, LCDML_0_1_2_3_5, 1, "50Hz", UI_func_eq_1);
LCDML_add(28, LCDML_0_1_2_3_5, 2, "110Hz", UI_func_eq_2);
LCDML_add(29, LCDML_0_1_2_3_5, 3, "220Hz", UI_func_eq_3);
LCDML_add(30, LCDML_0_1_2_3_5, 4, "1000Hz", UI_func_eq_4);
LCDML_add(31, LCDML_0_1_2_3_5, 5, "2000Hz", UI_func_eq_5);
LCDML_add(32, LCDML_0_1_2_3_5, 6, "7000Hz", UI_func_eq_6);
LCDML_add(33, LCDML_0_1_2_3_5, 7, "10000Hz", UI_func_eq_7);
LCDML_add(34, LCDML_0_1, 3, "Controller", NULL);
LCDML_add(35, LCDML_0_1_3, 1, "Pitchbend", NULL);
LCDML_add(36, LCDML_0_1_3_1, 1, "PB Range", UI_func_pb_range);
LCDML_add(37, LCDML_0_1_3_1, 2, "PB Step", UI_func_pb_step);
LCDML_add(38, LCDML_0_1_3, 2, "Mod Wheel", NULL);
LCDML_add(39, LCDML_0_1_3_2, 1, "MW Range", UI_func_mw_range);
LCDML_add(40, LCDML_0_1_3_2, 2, "MW Assign", UI_func_mw_assign);
LCDML_add(41, LCDML_0_1_3_2, 3, "MW Mode", UI_func_mw_mode);
LCDML_add(42, LCDML_0_1_3, 3, "Aftertouch", NULL);
LCDML_add(43, LCDML_0_1_3_3, 1, "AT Range", UI_func_at_range);
LCDML_add(44, LCDML_0_1_3_3, 2, "AT Assign", UI_func_at_assign);
LCDML_add(45, LCDML_0_1_3_3, 3, "AT Mode", UI_func_at_mode);
LCDML_add(46, LCDML_0_1_3, 4, "Foot Ctrl", NULL);
LCDML_add(47, LCDML_0_1_3_4, 1, "FC Range", UI_func_fc_range);
LCDML_add(48, LCDML_0_1_3_4, 2, "FC Assign", UI_func_fc_assign);
LCDML_add(49, LCDML_0_1_3_4, 3, "FC Mode", UI_func_fc_mode);
LCDML_add(50, LCDML_0_1_3, 5, "Breath Ctrl", NULL);
LCDML_add(51, LCDML_0_1_3_5, 1, "BC Range", UI_func_bc_range);
LCDML_add(52, LCDML_0_1_3_5, 2, "BC Assign", UI_func_bc_assign);
LCDML_add(53, LCDML_0_1_3_5, 3, "BC Mode", UI_func_bc_mode);
LCDML_add(54, LCDML_0_1, 4, "MIDI", NULL);
LCDML_add(55, LCDML_0_1_4, 1, "MIDI Channel", UI_func_midi_channel);
LCDML_add(56, LCDML_0_1_4, 2, "Lowest Note", UI_func_lowest_note);
LCDML_add(57, LCDML_0_1_4, 3, "Highest Note", UI_func_highest_note);
LCDML_add(58, LCDML_0_1_4, 4, "MIDI Send Voice", UI_func_sysex_send_voice);
LCDML_add(59, LCDML_0_1, 5, "Setup", NULL);
LCDML_add(60, LCDML_0_1_5, 1, "Portamento", NULL);
LCDML_add(61, LCDML_0_1_5_1, 1, "Port. Mode", UI_func_portamento_mode);
LCDML_add(62, LCDML_0_1_5_1, 2, "Port. Gliss", UI_func_portamento_glissando);
LCDML_add(63, LCDML_0_1_5_1, 3, "Port. Time", UI_func_portamento_time);
LCDML_add(64, LCDML_0_1_5, 2, "Polyphony", UI_func_polyphony);
LCDML_add(65, LCDML_0_1_5, 3, "Transpose", UI_func_transpose);
LCDML_add(66, LCDML_0_1_5, 4, "Fine Tune", UI_func_tune);
LCDML_add(67, LCDML_0_1_5, 5, "Mono/Poly", UI_func_mono_poly);
LCDML_add(68, LCDML_0_1, 6, "Internal", NULL);
LCDML_add(69, LCDML_0_1_6, 1, "Note Refresh", UI_func_note_refresh);
LCDML_add(70, LCDML_0_1_6, 2, "Velocity Lvl", UI_func_velocity_level);
LCDML_add(71, LCDML_0_1, 7, "Operator", UI_handle_OP);
LCDML_add(72, LCDML_0_1, 8, "Save Voice", UI_func_save_voice);
LCDML_add(73, LCDML_0, 3, "Load/Save", NULL);
LCDML_add(74, LCDML_0_3, 1, "Performance", NULL);
LCDML_add(75, LCDML_0_3_1, 1, "Load Perf.", UI_func_load_performance);
LCDML_add(76, LCDML_0_3_1, 2, "Save Perf.", UI_func_save_performance);
LCDML_add(77, LCDML_0_3, 2, "Voice Config", NULL);
LCDML_add(78, LCDML_0_3_2, 1, "Load Voice Cfg", UI_func_load_voiceconfig);
LCDML_add(79, LCDML_0_3_2, 2, "Save Voice Cfg", UI_func_save_voiceconfig);
LCDML_add(80, LCDML_0_3, 3, "Effects", NULL);
LCDML_add(81, LCDML_0_3_3, 1, "Load Effects", UI_func_load_fx);
LCDML_add(82, LCDML_0_3_3, 2, "Save Effects", UI_func_save_fx);
LCDML_add(83, LCDML_0_3, 5, "MIDI", NULL);
LCDML_add(84, LCDML_0_3_5, 1, "MIDI Recv Bank", UI_func_sysex_receive_bank);
LCDML_add(85, LCDML_0_3_5, 2, "MIDI Snd Bank", UI_func_sysex_send_bank);
LCDML_add(86, LCDML_0_3_5, 3, "MIDI Snd Voice", UI_func_sysex_send_voice);
LCDML_add(87, LCDML_0, 4, "Drums", NULL);
LCDML_add(88, LCDML_0_4, 1, "Drums Main Vol", UI_func_drums_main_volume);
LCDML_add(89, LCDML_0_4, 2, "Drum Volumes", UI_func_drum_volume);
LCDML_add(90, LCDML_0_4, 3, "Drum Pan", UI_func_drum_pan);
LCDML_add(91, LCDML_0_4, 4, "Drum Rev.Send", UI_func_drum_reverb_send);
LCDML_add(92, LCDML_0, 5, "Sequencer", NULL);
LCDML_add(93, LCDML_0_5, 1, "Sequencer", UI_func_sequencer);
LCDML_add(94, LCDML_0_5, 2, "Vel./Chrd Edit", UI_func_seq_vel_editor);
LCDML_add(95, LCDML_0_5, 3, "Pattern Chain", UI_func_seq_pat_chain);
LCDML_add(96, LCDML_0_5, 4, "Arpeggio", UI_func_arpeggio);
LCDML_add(97, LCDML_0_5, 5, "Seq. Settings", NULL);
LCDML_add(98, LCDML_0_5_5, 1, "Tempo", UI_func_seq_tempo);
LCDML_add(99, LCDML_0_5_5, 2, "Seq. Length", UI_func_seq_lenght);
LCDML_add(100, LCDML_0_5_5, 3, "Track Setup", UI_func_seq_track_setup);
LCDML_add(101, LCDML_0_5_5, 4, "Seq.Disp.Style", UI_func_seq_display_style);
LCDML_add(102, LCDML_0_5_5, 5, "dexed assign", UI_func_dexed_assign);
LCDML_add(103, LCDML_0_5_5, 6, "shift&transp.", UI_func_arp_shift);
LCDML_add(104, LCDML_0_5_5, 7, "L.Transp.Key", UI_func_seq_live_transpose_oct);
LCDML_add(105, LCDML_0_5_5, 8, "ChordTrack Keys", UI_func_seq_chord_keys_ammount);
LCDML_add(106, LCDML_0_5, 6, "LOAD Seq.Data", UI_func_seq_state_load);
LCDML_add(107, LCDML_0_5, 7, "SAVE Seq.Data", UI_func_seq_state_save);
LCDML_add(108, LCDML_0, 6, "System", NULL);
LCDML_add(109, LCDML_0_6, 1, "Stereo/Mono", UI_func_stereo_mono);
LCDML_add(110, LCDML_0_6, 2, "MIDI Soft THRU", UI_func_midi_soft_thru);
LCDML_add(111, LCDML_0_6, 3, "Favorites", UI_func_favorites);
LCDML_add(112, LCDML_0_6, 4, "EEPROM Reset", UI_func_eeprom_reset);
LCDML_add(113, LCDML_0, 7, "Info", UI_func_information);
LCDML_addAdvanced(114, LCDML_0, 8, COND_hide, "Volume", UI_func_volume, 0, _LCDML_TYPE_default);
#define _LCDML_DISP_cnt 114
#endif

@ -28,7 +28,6 @@
#include <Arduino.h>
#include "midinotes.h"
#include "teensy_board_detection.h"
#include "sgtl5000_graphic_eq.hpp"
// If you want to test the system with Linux and without any keyboard and/or audio equipment, you can do the following:
// 1. In Arduino-IDE enable "Tools->USB-Type->Serial + MIDI + Audio"
@ -183,38 +182,6 @@
#define SGTL5000_LINEOUT_LEVEL 29
#endif
#ifdef SGTL5000_AUDIO_ENHANCE
#define GRAPHIC_EQ_TYPE_0 bq_type_lowpass
#define GRAPHIC_EQ_CENTER_FRQ_0 115.0
#define GRAPHIC_EQ_Q_0 2.0
#define GRAPHIC_EQ_TYPE_1 bq_type_bandpass
#define GRAPHIC_EQ_CENTER_FRQ_1 330.0
#define GRAPHIC_EQ_Q_1 2.0
#define GRAPHIC_EQ_TYPE_2 bq_type_bandpass
#define GRAPHIC_EQ_CENTER_FRQ_2 990.0
#define GRAPHIC_EQ_Q_2 2.0
#define GRAPHIC_EQ_TYPE_3 bq_type_bandpass
#define GRAPHIC_EQ_CENTER_FRQ_3 2000.0
#define GRAPHIC_EQ_Q_3 2.0
#define GRAPHIC_EQ_TYPE_4 bq_type_bandpass
#define GRAPHIC_EQ_CENTER_FRQ_4 4000.0
#define GRAPHIC_EQ_Q_4 2.0
#define GRAPHIC_EQ_TYPE_5 bq_type_bandpass
#define GRAPHIC_EQ_CENTER_FRQ_5 9900.0
#define GRAPHIC_EQ_Q_5 2.0
#define GRAPHIC_EQ_TYPE_6 bq_type_highpass
#define GRAPHIC_EQ_CENTER_FRQ_6 11000.0
#define GRAPHIC_EQ_Q_6 2.0
#endif
//*************************************************************************************************
//* UI
//*************************************************************************************************
@ -389,10 +356,6 @@
#define USBCON 1
#endif
// Audio
#ifdef TGA_AUDIO_BOARD
#endif
// Some optimizations
#define USE_TEENSY_DSP 1
@ -641,25 +604,33 @@
#define VOICECONFIG_NUM_MAX MAX_VOICECONFIG
#define VOICECONFIG_NUM_DEFAULT -1
#define EQ_BASS_MIN -10
#define EQ_BASS_MAX 10
#define EQ_BASS_DEFAULT 0
#define EQ_1_MIN -10
#define EQ_1_MAX 10
#define EQ_1_DEFAULT 0
#define EQ_2_MIN -10
#define EQ_2_MAX 10
#define EQ_2_DEFAULT 0
#define EQ_3_MIN -10
#define EQ_3_MAX 10
#define EQ_3_DEFAULT 0
#define EQ_MIDBASS_MIN -10
#define EQ_MIDBASS_MAX 10
#define EQ_MIDBASS_DEFAULT 0
#define EQ_4_MIN -10
#define EQ_4_MAX 10
#define EQ_4_DEFAULT 0
#define EQ_MID_MIN -10
#define EQ_MID_MAX 10
#define EQ_MID_DEFAULT 0
#define EQ_5_MIN -10
#define EQ_5_MAX 10
#define EQ_5_DEFAULT 0
#define EQ_MIDTREBLE_MIN -10
#define EQ_MIDTREBLE_MAX 10
#define EQ_MIDTREBLE_DEFAULT 0
#define EQ_6_MIN -10
#define EQ_6_MAX 10
#define EQ65_DEFAULT 0
#define EQ_TREBLE_MIN -10
#define EQ_TREBLE_MAX 10
#define EQ_TREBLE_DEFAULT 0
#define EQ_7_MIN -10
#define EQ_7_MAX 10
#define EQ_7_DEFAULT 0
// Buffer for load/save configuration as JSON
@ -717,11 +688,13 @@ typedef struct fx_s {
uint8_t reverb_hidamp;
uint8_t reverb_diffusion;
uint8_t reverb_level;
int8_t eq_bass;
int8_t eq_midbass;
int8_t eq_mid;
int8_t eq_midtreble;
int8_t eq_treble;
int8_t eq_1;
int8_t eq_2;
int8_t eq_3;
int8_t eq_4;
int8_t eq_5;
int8_t eq_6;
int8_t eq_7;
} fx_t;
typedef struct performance_s {

@ -0,0 +1,143 @@
/*
MicroDexed
MicroDexed is a port of the Dexed sound engine
(https://github.com/asb2m10/dexed) for the Teensy-3.5/3.6/4.x with audio shield.
Dexed ist heavily based on https://github.com/google/music-synthesizer-for-android
(c)2018-2021 H. Wirtz <wirtz@parasitstudio.de>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software Foundation,
Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <Arduino.h>
#include <Audio.h>
#include "control_sgtl5000plus.h"
void AudioControlSGTL5000Plus::init_parametric_eq(void)
{
eqSelect(PARAMETRIC_EQUALIZER);
eqFilterCount(num_bands);
filter_type = new uint8_t[num_bands];
Fc = new float[num_bands];
Q = new float[num_bands];
peakGainDB = new float[num_bands];
setEQType(1, GRAPHIC_EQ_TYPE_0);
setEQFc(1, GRAPHIC_EQ_CENTER_FRQ_0);
setEQQ(1, GRAPHIC_EQ_Q_0);
setEQGain(1, 0.0);
if (num_bands > 1)
{
setEQType(2, GRAPHIC_EQ_TYPE_1);
setEQFc(2, GRAPHIC_EQ_CENTER_FRQ_1);
setEQQ(2, GRAPHIC_EQ_Q_1);
setEQGain(2, 0.0);
}
if (num_bands > 2)
{
setEQType(3, GRAPHIC_EQ_TYPE_2);
setEQFc(3, GRAPHIC_EQ_CENTER_FRQ_2);
setEQQ(3, GRAPHIC_EQ_Q_2);
setEQGain(3, 0.0);
}
if (num_bands > 3)
{
setEQType(4, GRAPHIC_EQ_TYPE_3);
setEQFc(4, GRAPHIC_EQ_CENTER_FRQ_3);
setEQQ(4, GRAPHIC_EQ_Q_3);
setEQGain(4, 0.0);
}
if (num_bands > 4)
{
setEQType(5, GRAPHIC_EQ_TYPE_4);
setEQFc(5, GRAPHIC_EQ_CENTER_FRQ_4);
setEQQ(5, GRAPHIC_EQ_Q_4);
setEQGain(5, 0.0);
}
if (num_bands > 5)
{
setEQType(6, GRAPHIC_EQ_TYPE_5);
setEQFc(6, GRAPHIC_EQ_CENTER_FRQ_5);
setEQQ(6, GRAPHIC_EQ_Q_5);
setEQGain(6, 0.0);
}
if (num_bands > 6)
{
setEQType(7, GRAPHIC_EQ_TYPE_6);
setEQFc(7, GRAPHIC_EQ_CENTER_FRQ_6);
setEQQ(7, GRAPHIC_EQ_Q_6);
setEQGain(7, 0.0);
}
}
void AudioControlSGTL5000Plus::setEQType(uint8_t band, uint8_t ft)
{
if (filter_type)
{
int filter[5];
band = constrain(band, 1, num_bands);
filter_type[band - 1] = ft;
calcBiquad(filter_type[band - 1], Fc[band - 1], peakGainDB[band - 1], Q[band - 1], 524288, AUDIO_SAMPLE_RATE, filter);
//eqFilter(band, filter);
}
}
void AudioControlSGTL5000Plus::setEQFc(uint8_t band, float frq)
{
if (Fc)
{
int filter[5];
band = constrain(band, 1, num_bands);
Fc[band - 1] = frq;
calcBiquad(filter_type[band - 1], Fc[band - 1], peakGainDB[band - 1], Q[band - 1], 524288, AUDIO_SAMPLE_RATE, filter);
//eqFilter(band, filter);
}
}
void AudioControlSGTL5000Plus::setEQQ(uint8_t band, float q)
{
if (Q)
{
int filter[5];
band = constrain(band, 1, num_bands);
Q[band - 1] = q;
calcBiquad(filter_type[band - 1], Fc[band - 1], peakGainDB[band - 1], Q[band - 1], 524288, AUDIO_SAMPLE_RATE, filter);
//eqFilter(band, filter);
}
}
void AudioControlSGTL5000Plus::setEQGain(uint8_t band, float gain)
{
if (peakGainDB)
{
int filter[5];
band = constrain(band, 1, num_bands);
peakGainDB[band - 1] = gain;
calcBiquad(filter_type[band - 1], Fc[band - 1], peakGainDB[band - 1], Q[band - 1], 524288, AUDIO_SAMPLE_RATE, filter);
//eqFilter(band, filter);
}
}

@ -0,0 +1,80 @@
/*
MicroDexed
MicroDexed is a port of the Dexed sound engine
(https://github.com/asb2m10/dexed) for the Teensy-3.5/3.6/4.x with audio shield.
Dexed ist heavily based on https://github.com/google/music-synthesizer-for-android
(c)2018-2021 H. Wirtz <wirtz@parasitstudio.de>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software Foundation,
Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifndef _SGTL5000PLUS_H_
#define _SGTL5000PLUS_H_
#include <Arduino.h>
#include <Audio.h>
#define GRAPHIC_EQ_TYPE_0 FILTER_HIPASS
#define GRAPHIC_EQ_CENTER_FRQ_0 50.0
#define GRAPHIC_EQ_Q_0 6.0
#define GRAPHIC_EQ_TYPE_1 FILTER_BANDPASS
#define GRAPHIC_EQ_CENTER_FRQ_1 120.0
#define GRAPHIC_EQ_Q_1 6.0
#define GRAPHIC_EQ_TYPE_2 FILTER_BANDPASS
#define GRAPHIC_EQ_CENTER_FRQ_2 220.0
#define GRAPHIC_EQ_Q_2 6.0
#define GRAPHIC_EQ_TYPE_3 FILTER_BANDPASS
#define GRAPHIC_EQ_CENTER_FRQ_3 1000.0
#define GRAPHIC_EQ_Q_3 6.0
#define GRAPHIC_EQ_TYPE_4 FILTER_BANDPASS
#define GRAPHIC_EQ_CENTER_FRQ_4 2000.0
#define GRAPHIC_EQ_Q_4 6.0
#define GRAPHIC_EQ_TYPE_5 FILTER_BANDPASS
#define GRAPHIC_EQ_CENTER_FRQ_5 7000.0
#define GRAPHIC_EQ_Q_5 2.0
#define GRAPHIC_EQ_TYPE_6 FILTER_LOPASS
#define GRAPHIC_EQ_CENTER_FRQ_6 10000.0
#define GRAPHIC_EQ_Q_6 6.0
class AudioControlSGTL5000Plus : public AudioControlSGTL5000
{
public:
AudioControlSGTL5000Plus(uint8_t n = 7) {
num_bands = constrain(n, 1, 7);
init_parametric_eq();
};
void setEQType(uint8_t band, uint8_t ft);
void setEQFc(uint8_t band, float frq);
void setEQQ(uint8_t band, float q);
void setEQGain(uint8_t band, float gain);
private:
void init_parametric_eq(void);
uint8_t num_bands;
int* filter_coeff;
uint8_t* filter_type;
float* Fc;
float* Q;
float* peakGainDB;
};
#endif

@ -662,8 +662,13 @@ bool load_sd_fx_json(int8_t fx)
configuration.fx.reverb_hidamp = data_json["reverb_hidamp"];
configuration.fx.reverb_diffusion = data_json["reverb_diffusion"];
configuration.fx.reverb_level = data_json["reverb_level"];
configuration.fx.eq_bass = data_json["eq_bass"];
configuration.fx.eq_treble = data_json["eq_treble"];
configuration.fx.eq_1 = data_json["eq_1"];
configuration.fx.eq_2 = data_json["eq_2"];
configuration.fx.eq_3 = data_json["eq_3"];
configuration.fx.eq_4 = data_json["eq_4"];
configuration.fx.eq_5 = data_json["eq_5"];
configuration.fx.eq_6 = data_json["eq_6"];
configuration.fx.eq_7 = data_json["eq_7"];
set_fx_params();
@ -734,9 +739,13 @@ bool save_sd_fx_json(uint8_t fx)
data_json["reverb_hidamp"] = configuration.fx.reverb_hidamp;
data_json["reverb_diffusion"] = configuration.fx.reverb_diffusion;
data_json["reverb_level"] = configuration.fx.reverb_level;
data_json["eq_bass"] = configuration.fx.eq_bass;
data_json["eq_treble"] = configuration.fx.eq_treble;
data_json["eq_1"] = configuration.fx.eq_1;
data_json["eq_2"] = configuration.fx.eq_2;
data_json["eq_3"] = configuration.fx.eq_3;
data_json["eq_4"] = configuration.fx.eq_4;
data_json["eq_5"] = configuration.fx.eq_5;
data_json["eq_6"] = configuration.fx.eq_6;
data_json["eq_7"] = configuration.fx.eq_7;
#ifdef DEBUG
Serial.println(F("Write JSON data:"));
serializeJsonPretty(data_json, Serial);
@ -807,7 +816,7 @@ bool load_sd_seq_drumsettings_json(uint8_t number)
// drum_config[i].vol_min = data_json["vol_min"][i] ;
// drum_config[i].reverb_send = data_json["reverb_send"][i];
}
set_fx_params();
//set_fx_params();
return (true);
}
@ -831,6 +840,7 @@ bool load_sd_seq_drumsettings_json(uint8_t number)
AudioInterrupts();
return (false);
}
bool load_sd_seq_voicesettings_json(uint8_t number)
{
uint8_t bank[MAX_DEXED];
@ -883,6 +893,7 @@ bool load_sd_seq_voicesettings_json(uint8_t number)
configuration.dexed[i].transpose = data_json["v_trans"][i];
}
/*
configuration.fx.reverb_roomsize = data_json["rev_roomsize"];
configuration.fx.reverb_damping = data_json["rev_damping"];
configuration.fx.reverb_lowpass = data_json["rev_lowpass"];
@ -891,7 +902,7 @@ bool load_sd_seq_voicesettings_json(uint8_t number)
configuration.fx.reverb_diffusion = data_json["rev_diffusion"];
configuration.fx.reverb_level = data_json["rev_level"];
configuration.fx.eq_bass = data_json["eq_bass"];
configuration.fx.eq_treble = data_json["eq_treble"];
configuration.fx.eq_treble = data_json["eq_treble"]; */
for (uint8_t i = 0; i < NUM_DEXED; i++)
{
@ -903,7 +914,7 @@ bool load_sd_seq_voicesettings_json(uint8_t number)
seq_tempo_ms = 60000000 / seq_bpm / 4;
timer1.begin(sequencer, seq_tempo_ms / 2, false);
set_fx_params();
//set_fx_params();
return (true);
}
@ -927,7 +938,6 @@ bool load_sd_seq_voicesettings_json(uint8_t number)
return (false);
}
bool save_sd_seq_drumsettings_json(uint8_t number)
{
char filename[FILENAME_LEN];
@ -982,6 +992,7 @@ bool save_sd_seq_drumsettings_json(uint8_t number)
AudioInterrupts();
return (false);
}
bool save_sd_seq_voicesettings_json(uint8_t number)
{
char filename[FILENAME_LEN];
@ -1015,6 +1026,7 @@ bool save_sd_seq_voicesettings_json(uint8_t number)
data_json["v_trans"][i] = configuration.dexed[i].transpose;
}
/*
data_json["rev_roomsize"] = configuration.fx.reverb_roomsize;
data_json["rev_damping"] = configuration.fx.reverb_damping;
data_json["rev_lowpass"] = configuration.fx.reverb_lowpass;
@ -1023,7 +1035,7 @@ bool save_sd_seq_voicesettings_json(uint8_t number)
data_json["rev_diffusion"] = configuration.fx.reverb_diffusion;
data_json["rev_level"] = configuration.fx.reverb_level;
data_json["eq_bass"] = configuration.fx.eq_bass;
data_json["eq_treble"] = configuration.fx.eq_treble;
data_json["eq_treble"] = configuration.fx.eq_treble; */
#ifdef DEBUG
Serial.println(F("Write JSON data:"));
@ -1146,6 +1158,25 @@ bool save_sd_seq_json(uint8_t seq_number)
data_json["seq_oct_shift"] = seq_oct_shift;
data_json["seq_element_shift"] = seq_element_shift;
/*
<<<<<<< HEAD
data_json["reverb_roomsize"] = configuration.fx.reverb_roomsize;
data_json["reverb_damping"] = configuration.fx.reverb_damping;
data_json["reverb_lowpass"] = configuration.fx.reverb_lowpass;
data_json["reverb_lodamp"] = configuration.fx.reverb_lodamp;
data_json["reverb_hidamp"] = configuration.fx.reverb_hidamp;
data_json["reverb_diffusion"] = configuration.fx.reverb_diffusion;
data_json["reverb_level"] = configuration.fx.reverb_level;
data_json["eq_1"] = configuration.fx.eq_1;
data_json["eq_2"] = configuration.fx.eq_2;
data_json["eq_3"] = configuration.fx.eq_3;
data_json["eq_4"] = configuration.fx.eq_4;
data_json["eq_5"] = configuration.fx.eq_5;
data_json["eq_6"] = configuration.fx.eq_6;
data_json["eq_7"] = configuration.fx.eq_7;
=======
*/
for (uint8_t i = 0; i < sizeof(seq_track_type); i++) {
data_json["track_type"][i] = seq_track_type[i];
}
@ -1156,6 +1187,7 @@ bool save_sd_seq_json(uint8_t seq_number)
data_json["seq_inst_dexed"][i] = seq_inst_dexed[i];
}
//>>>>>>> 4af597461ea0ae5e49069d309862018eb651ccb4
#ifdef DEBUG
Serial.println(F("Write JSON data:"));
serializeJsonPretty(data_json, Serial);
@ -1264,6 +1296,24 @@ bool load_sd_seq_json(uint8_t seq_number)
for (uint8_t i = 0; i < sizeof(seq_inst_dexed); i++) {
seq_inst_dexed[i] = data_json["seq_inst_dexed"][i];
}
/*
<<<<<<< HEAD
configuration.fx.reverb_roomsize = data_json["reverb_roomsize"];
configuration.fx.reverb_damping = data_json["reverb_damping"];
configuration.fx.reverb_lowpass = data_json["reverb_lowpass"];
configuration.fx.reverb_lodamp = data_json["reverb_lodamp"];
configuration.fx.reverb_hidamp = data_json["reverb_hidamp"];
configuration.fx.reverb_diffusion = data_json["reverb_diffusion"];
configuration.fx.reverb_level = data_json["reverb_level"];
configuration.fx.eq_1 = data_json["eq_1"];
configuration.fx.eq_2 = data_json["eq_2"];
configuration.fx.eq_3 = data_json["eq_3"];
configuration.fx.eq_4 = data_json["eq_4"];
configuration.fx.eq_5 = data_json["eq_5"];
configuration.fx.eq_6 = data_json["eq_6"];
configuration.fx.eq_7 = data_json["eq_7"];
=======
*/
count = 0;
seq_tempo_ms = data_json["seq_tempo_ms"] ;
@ -1279,8 +1329,9 @@ bool load_sd_seq_json(uint8_t seq_number)
seq_chord_key_ammount = data_json["chord_key_ammount"];
seq_oct_shift = data_json["seq_oct_shift"];
seq_element_shift = data_json["seq_element_shift"];
//>>>>>>> 4af597461ea0ae5e49069d309862018eb651ccb4
set_fx_params();
//set_fx_params();
return (true);
}
@ -1304,6 +1355,7 @@ bool load_sd_seq_json(uint8_t seq_number)
AudioInterrupts();
return (false);
}
bool check_sd_seq_exists(uint8_t number)
{
if (number < 0)

@ -1,188 +0,0 @@
#ifdef SGTL5000_AUDIO_ENHANCE
#include <Arduino.h>
#include <Audio.h>
extern AudioControlSGTL5000 sgtl5000_1;
typedef struct biquad_coefficients_s {
float32_t a0;
float32_t a1;
float32_t a2;
float32_t b1;
float32_t b2;
} biquad_coefficients_t;
typedef struct biquad_params_s {
uint8_t filter_type;
float32_t Fc;
float32_t Q;
} biquad_params_t;
enum {
bq_type_lowpass = 0,
bq_type_highpass,
bq_type_bandpass,
bq_type_notch,
bq_type_peak,
bq_type_lowshelf,
bq_type_highshelf
};
#define NUM_GRAPHIC_EQ_BANDS 7
biquad_coefficients_t biquad_coefficients[NUM_GRAPHIC_EQ_BANDS];
biquad_params_t biquad_params[NUM_GRAPHIC_EQ_BANDS];
void set_sgtl5000_7band_eq(uint8_t band, uint8_t filter_type, float32_t Fc, float32_t Q);
void set_sgtl5000_7band_eq_gain(uint8_t band, float32_t peakGainDB);
void setup_sgtl5000_graphic_7band_eq(void);
void calcBiquadCoefficients(biquad_coefficients_t* biquad_coefficients, uint8_t filter_type, float32_t Fc, float32_t Q, float32_t peakGain);
void set_sgtl5000_7band_eq(uint8_t band, uint8_t filter_type, float32_t Fc, float32_t Q)
{
biquad_params[band].filter_type = filter_type;
biquad_params[band].Fc = Fc;
biquad_params[band].Q = Q;
calcBiquadCoefficients(&biquad_coefficients[band], filter_type, Fc, Q, 0.0);
//sgtl5000_1.eqFilter(band, biquad_coefficients);
}
void set_sgtl5000_7band_eq_gain(uint8_t band, float32_t peakGainDB)
{
calcBiquadCoefficients(&biquad_coefficients[band], biquad_params[band].filter_type, biquad_params[band].Fc, biquad_params[band].Q, peakGainDB);
//sgtl5000_1.eqFilter(band, biquad_coefficients);
}
void setup_sgtl5000_graphic_7band_eq(void)
{
//sgtl5000_1.eqFilterCount(7); // enable 7 bands
set_sgtl5000_7band_eq(0, GRAPHIC_EQ_TYPE_0, GRAPHIC_EQ_CENTER_FRQ_0, GRAPHIC_EQ_Q_0);
set_sgtl5000_7band_eq(1, GRAPHIC_EQ_TYPE_1, GRAPHIC_EQ_CENTER_FRQ_1, GRAPHIC_EQ_Q_1);
set_sgtl5000_7band_eq(2, GRAPHIC_EQ_TYPE_2, GRAPHIC_EQ_CENTER_FRQ_2, GRAPHIC_EQ_Q_2);
set_sgtl5000_7band_eq(3, GRAPHIC_EQ_TYPE_3, GRAPHIC_EQ_CENTER_FRQ_3, GRAPHIC_EQ_Q_3);
set_sgtl5000_7band_eq(4, GRAPHIC_EQ_TYPE_4, GRAPHIC_EQ_CENTER_FRQ_4, GRAPHIC_EQ_Q_4);
set_sgtl5000_7band_eq(5, GRAPHIC_EQ_TYPE_5, GRAPHIC_EQ_CENTER_FRQ_5, GRAPHIC_EQ_Q_5);
set_sgtl5000_7band_eq(6, GRAPHIC_EQ_TYPE_6, GRAPHIC_EQ_CENTER_FRQ_6, GRAPHIC_EQ_Q_6);
}
// Taken from https://www.earlevel.com/main/2012/11/26/biquad-c-source-code/
//
// Biquad.h
//
// Created by Nigel Redmon on 11/24/12
// EarLevel Engineering: earlevel.com
// Copyright 2012 Nigel Redmon
//
// For a complete explanation of the Biquad code:
// http://www.earlevel.com/main/2012/11/25/biquad-c-source-code/
//
// License:
//
// This source code is provided as is, without warranty.
// You may copy and distribute verbatim copies of this document.
// You may modify and use this source code to create binary code
// for your own purposes, free or commercial.
//
void calcBiquadCoefficients(biquad_coefficients_t* biquad_coefficients, uint8_t filter_type, float32_t Fc, float32_t Q, float32_t peakGain)
{
float32_t norm;
float32_t V = pow(10, fabs(peakGain) / 20.0);
float32_t K = tan(M_PI * Fc);
switch (filter_type) {
case bq_type_lowpass:
norm = 1 / (1 + K / Q + K * K);
biquad_coefficients->a0 = K * K * norm;
biquad_coefficients->a1 = 2 * biquad_coefficients->a0;
biquad_coefficients->a2 = biquad_coefficients->a0;
biquad_coefficients->b1 = 2 * (K * K - 1) * norm;
biquad_coefficients->b2 = (1 - K / Q + K * K) * norm;
break;
case bq_type_highpass:
norm = 1 / (1 + K / Q + K * K);
biquad_coefficients->a0 = 1 * norm;
biquad_coefficients->a1 = -2 * biquad_coefficients->a0;
biquad_coefficients->a2 = biquad_coefficients->a0;
biquad_coefficients->b1 = 2 * (K * K - 1) * norm;
biquad_coefficients->b2 = (1 - K / Q + K * K) * norm;
break;
case bq_type_bandpass:
norm = 1 / (1 + K / Q + K * K);
biquad_coefficients->a0 = K / Q * norm;
biquad_coefficients->a1 = 0;
biquad_coefficients->a2 = -biquad_coefficients->a0;
biquad_coefficients->b1 = 2 * (K * K - 1) * norm;
biquad_coefficients->b2 = (1 - K / Q + K * K) * norm;
break;
case bq_type_notch:
norm = 1 / (1 + K / Q + K * K);
biquad_coefficients->a0 = (1 + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - 1) * norm;
biquad_coefficients->a2 = biquad_coefficients->a0;
biquad_coefficients->b1 = biquad_coefficients->a1;
biquad_coefficients->b2 = (1 - K / Q + K * K) * norm;
break;
case bq_type_peak:
if (peakGain >= 0) { // boost
norm = 1 / (1 + 1 / Q * K + K * K);
biquad_coefficients->a0 = (1 + V / Q * K + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - 1) * norm;
biquad_coefficients->a2 = (1 - V / Q * K + K * K) * norm;
biquad_coefficients->b1 = biquad_coefficients->a1;
biquad_coefficients->b2 = (1 - 1 / Q * K + K * K) * norm;
}
else { // cut
norm = 1 / (1 + V / Q * K + K * K);
biquad_coefficients->a0 = (1 + 1 / Q * K + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - 1) * norm;
biquad_coefficients->a2 = (1 - 1 / Q * K + K * K) * norm;
biquad_coefficients->b1 = biquad_coefficients->a1;
biquad_coefficients->b2 = (1 - V / Q * K + K * K) * norm;
}
break;
case bq_type_lowshelf:
if (peakGain >= 0) { // boost
norm = 1 / (1 + sqrt(2) * K + K * K);
biquad_coefficients->a0 = (1 + sqrt(2 * V) * K + V * K * K) * norm;
biquad_coefficients->a1 = 2 * (V * K * K - 1) * norm;
biquad_coefficients->a2 = (1 - sqrt(2 * V) * K + V * K * K) * norm;
biquad_coefficients->b1 = 2 * (K * K - 1) * norm;
biquad_coefficients->b2 = (1 - sqrt(2) * K + K * K) * norm;
}
else { // cut
norm = 1 / (1 + sqrt(2 * V) * K + V * K * K);
biquad_coefficients->a0 = (1 + sqrt(2) * K + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - 1) * norm;
biquad_coefficients->a2 = (1 - sqrt(2) * K + K * K) * norm;
biquad_coefficients->b1 = 2 * (V * K * K - 1) * norm;
biquad_coefficients->b2 = (1 - sqrt(2 * V) * K + V * K * K) * norm;
}
break;
case bq_type_highshelf:
if (peakGain >= 0) { // boost
norm = 1 / (1 + sqrt(2) * K + K * K);
biquad_coefficients->a0 = (V + sqrt(2 * V) * K + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - V) * norm;
biquad_coefficients->a2 = (V - sqrt(2 * V) * K + K * K) * norm;
biquad_coefficients->b1 = 2 * (K * K - 1) * norm;
biquad_coefficients->b2 = (1 - sqrt(2) * K + K * K) * norm;
}
else { // cut
norm = 1 / (V + sqrt(2 * V) * K + K * K);
biquad_coefficients->a0 = (1 + sqrt(2) * K + K * K) * norm;
biquad_coefficients->a1 = 2 * (K * K - 1) * norm;
biquad_coefficients->a2 = (1 - sqrt(2) * K + K * K) * norm;
biquad_coefficients->b1 = 2 * (K * K - V) * norm;
biquad_coefficients->b2 = (V - sqrt(2 * V) * K + K * K) * norm;
}
break;
}
return;
}
#endif

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@ -0,0 +1,21 @@
MIT License
Copyright (c) 2019 Lutz Niggl
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.

@ -0,0 +1,7 @@
# TeensyTimerTool
The TeensyTimerTool is a library that provides a generic, easy to use interface to the hardware timers of the PJRC Teensy boards. In addition, it provides up to 20 highly efficient software timers that use the same interface. All timers can be used in periodic and one-shot mode. Currently the library supports the ARM T3.X and T4.0 boards.
- This way to the corresponding PJRC **[forum post](https://forum.pjrc.com/threads/59112-TeensyTimerTool)**
- This way to the documentation in the **[TeensyTimerTool WIKI](https://github.com/luni64/TeensyTimerTool/wiki)**

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After

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@ -0,0 +1,31 @@
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
//Timer t[]{FTM0, FTM0, FTM2}; // two channels from FTM0, one from FTM2
//Timer t[3]; // use 3 timers from the pool
OneShotTimer t[]{FTM0, FTM0, FTM0, FTM0, FTM0, FTM0, FTM0, FTM0}; // all 8 channels of FTM0
constexpr unsigned nrOfTimers = sizeof(t) / sizeof(t[0]);
void setup()
{
// setup timers, use lambdas as callbacks
for (unsigned i = 0; i < nrOfTimers; i++)
{
pinMode(i, OUTPUT);
t[i].begin([i] { digitalWriteFast(i, LOW); }); // callback resets pin to LOW
}
}
void loop()
{
for (unsigned i = 0; i < nrOfTimers; i++)
{
digitalWriteFast(i, HIGH);
t[i].trigger(50 * (i + 1)); // 50, 100, 150 ... µs
}
delay(1);
}

@ -0,0 +1,3 @@
Measured output of the example sketch
![Output](./../../assets/FTM0_8CH.jpg)

@ -0,0 +1,26 @@
#include "Arduino.h"
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
void callback()
{
digitalWriteFast(LED_BUILTIN, LOW); // switch off LED
}
OneShotTimer timer1; // generate a timer from the pool (Pool: 2xGPT, 16xTMR(QUAD), 20xTCK)
void setup()
{
pinMode(LED_BUILTIN,OUTPUT);
timer1.begin(callback);
}
void loop()
{
digitalWriteFast(LED_BUILTIN, HIGH);
timer1.trigger(10'000); // switch of after 10ms
delay(500);
}

@ -0,0 +1,29 @@
/********************************************************
* Basic usage of the timer
*
* Generates a timer from the timer pool and
* starts it with a period of 250ms.
* The timer callback simply toggles the built in LED
*
********************************************************/
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
void callback()
{
digitalWriteFast(LED_BUILTIN, !digitalReadFast(LED_BUILTIN));
}
Timer t1; // generate a timer from the pool (Pool: 2xGPT, 16xTMR(QUAD), 20xTCK)
void setup()
{
pinMode(LED_BUILTIN,OUTPUT);
t1.beginPeriodic(callback, 250'000); // 250ms
}
void loop()
{
}

@ -0,0 +1,52 @@
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
Timer t1(TCK); // Tick-Timer does not use any hardware timer (20 32bit channels)
Timer t2(TMR1); // First channel on TMR1 aka QUAD timer module. (TMR1 - TMR4, four 16bit channels each)
Timer t3(GPT1); // GPT1 module (one 32bit channel per module)
Timer t4(TMR1); // Second channel on TMR1
// Callbacks ===================================================================================
void pulse200ns()
{
digitalWriteFast(1, HIGH);
delayNanoseconds(200);
digitalWriteFast(1, LOW);
}
void pulse400ns()
{
digitalWriteFast(2, HIGH);
delayNanoseconds(400);
digitalWriteFast(2, LOW);
}
void LED_ON()
{
digitalWriteFast(LED_BUILTIN, HIGH); // LED On
t4.trigger(10'000); // trigger t4 to switch of after 10ms
}
void LED_OFF()
{
digitalWriteFast(LED_BUILTIN, LOW);
}
//================================================================================================
void setup()
{
for(unsigned pin = 0; pin <=13; pin++) pinMode(pin,OUTPUT);
t1.beginPeriodic(pulse200ns, 50'000); // 200ns pulse every 500 ms
t2.beginPeriodic(pulse400ns, 100); // 400ns pulse every 100 µs
t3.beginPeriodic(LED_ON, 1'000'000); // Switch LED on every second
t4.beginOneShot(LED_OFF); // One shot timer to switch LED Off
}
void loop()
{
}

@ -0,0 +1,35 @@
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
PeriodicTimer t1(TCK);
PeriodicTimer t2(TCK);
void isr1()
{
Serial.printf("called @: %u ms\n", millis());
}
void isr2()
{
digitalToggleFast(LED_BUILTIN);
}
void isr3()
{
digitalWriteFast(0,HIGH);
delayMicroseconds(10);
digitalWriteFast(0, LOW);
}
void setup()
{
pinMode(LED_BUILTIN, OUTPUT);
t1.begin(isr1, 5.02s); // instead of 5020000 (µs)
t2.begin(isr2, 25ms); // instead of 25000 (µs)
t2.begin(isr3, 100_kHz); // instead of 10 (µs)
}
void loop()
{
}

@ -0,0 +1,33 @@
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
OneShotTimer timer[]{TCK, TCK, TCK, TCK}; // 4 one-shot-timers
PeriodicTimer pt1; // 1 periodic timer
unsigned t_0; // start time
void isr()
{
Serial.printf("called @: %u ms\n", millis() - t_0);
}
void setup()
{
while (!Serial) {} // wait for PC to connect the virtual serial port
for (OneShotTimer& t : timer) // for the sake of simplicity, attach the same isr to all timers in array
{
t.begin(isr);
}
timer[0].trigger(10ms); // 10 ms
timer[1].trigger(0.5s + 10ms); // 510 ms
timer[2].trigger(2.5 * 0.3s + 20'000us / 2); // 760 ms
timer[3].trigger(milliseconds(50) + microseconds(5000)); // 55ms
t_0 = millis();
pt1.begin([]{digitalToggleFast(LED_BUILTIN)})
}
void loop()
{
}

@ -0,0 +1,29 @@
#include "TeensyTimerTool.h"
using namespace TeensyTimerTool;
void callback(int& someInt, int cnt) // this callback has context, i.e. parameter
{
for (int i = 0; i < cnt; i++) // whenn called, print out someInt cnt times
{
Serial.print(someInt);
Serial.print(" | ");
}
Serial.println();
}
//==============================================================
Timer t;
int number = 0;
void setup()
{
t.beginPeriodic([] { callback(number, 5); }, 50'000);
}
void loop()
{
number++; // change every second
delay(1000);
}

@ -0,0 +1,21 @@
#include "TeensyTimerTool.h"
#include "pins.h"
using namespace TeensyTimerTool;
using namespace pins;
pin<13> LED(OUTPUT);
Timer timer;
void setup()
{
timer.beginOneShot([] { LED = LOW; });
}
void loop()
{
LED = HIGH;
timer.trigger(25'000);
delay(1'000);
}

@ -0,0 +1,253 @@
#pragma once
#include <stdint.h>
#include <core_pins.h>
#include <type_traits>
namespace pins
{
namespace // private
{
enum boards {
notDefined = -1,
T_LC,
T3_0_1_2,
T3_5_6,
};
#if defined(__MKL26Z64__)
constexpr boards board = boards::T_LC;
#elif defined(__MK20DX128__) || defined(__MK20DX256__)
constexpr boards board = boards::T3_0_1_2;
#elif defined(__MK64FX512__) || defined(__MK66FX1M0__)
constexpr boards board = boards::T3_5_6;
#else
constexpr boards board = boards::notDefined;
#endif
static_assert(board != boards::notDefined, "Error in Pin.h");
// Indices into GPIOx and PORT arrays below
enum portList {
na = -1, Port_A, Port_B, Port_C, Port_D, Port_E
};
//Base adresses of the GPIOx register blocks
constexpr uintptr_t GPIOx_PDOR[] =
{
(uintptr_t)&(GPIOA_PDOR),
(uintptr_t)&(GPIOB_PDOR),
(uintptr_t)&(GPIOC_PDOR),
(uintptr_t)&(GPIOD_PDOR),
(uintptr_t)&(GPIOE_PDOR),
};
// Base adresses of the Pin Control Registers
constexpr uintptr_t PORTx_PCR0[] =
{
(uintptr_t)&(PORTA_PCR0),
(uintptr_t)&(PORTB_PCR0),
(uintptr_t)&(PORTC_PCR0),
(uintptr_t)&(PORTD_PCR0),
(uintptr_t)&(PORTE_PCR0),
};
//----------------------------------------------------------------
// Translate Teensy pin number to port and bitnr
// The map will be used by the complier only, no code will be generated
struct pinInfo {
const portList port;
const int pin;
};
constexpr pinInfo pinMap[][3] =
{ // T-LC T3.0/1/2 T3.5/6
/* Pin 0 */{ { Port_B, 16 },{ Port_B, 16 },{ Port_B, 16 } },
/* Pin 1 */{ { Port_B, 17 },{ Port_B, 17 },{ Port_B, 17 } },
/* Pin 2 */{ { Port_D, 0 },{ Port_D, 0 },{ Port_D, 0 } },
/* Pin 3 */{ { Port_A, 1 },{ Port_A, 12 },{ Port_A, 12 } },
/* Pin 4 */{ { Port_A, 2 },{ Port_A, 13 },{ Port_A, 13 } },
/* Pin 5 */{ { Port_D, 7 },{ Port_D, 7 },{ Port_D, 7 } },
/* Pin 6 */{ { Port_D, 4 },{ Port_D, 4 },{ Port_D, 4 } },
/* Pin 7 */{ { Port_D, 2 },{ Port_D, 2 },{ Port_D, 2 } },
/* Pin 8 */{ { Port_D, 3 },{ Port_D, 3 },{ Port_D, 3 } },
/* Pin 9 */{ { Port_C, 3 },{ Port_C, 3 },{ Port_C, 3 } },
/* Pin 10*/{ { Port_C, 4 },{ Port_C, 4 },{ Port_C, 4 } },
/* Pin 11*/{ { Port_C, 6 },{ Port_C, 6 },{ Port_C, 6 } },
/* Pin 12*/{ { Port_C, 7 },{ Port_C, 7 },{ Port_C, 7 } },
/* Pin 13*/{ { Port_C, 5 },{ Port_C, 5 },{ Port_C, 5 } },
/* Pin 14*/{ { Port_D, 1 },{ Port_D, 1 },{ Port_D, 1 } },
/* Pin 15*/{ { Port_C, 0 },{ Port_C, 0 },{ Port_C, 0 } },
/* Pin 16*/{ { Port_B, 0 },{ Port_B, 0 },{ Port_B, 0 } },
/* Pin 17*/{ { Port_B, 1 },{ Port_B, 1 },{ Port_B, 1 } },
/* Pin 18*/{ { Port_B, 3 },{ Port_B, 3 },{ Port_B, 3 } },
/* Pin 19*/{ { Port_B, 2 },{ Port_B, 2 },{ Port_B, 2 } },
/* Pin 20*/{ { Port_D, 5 },{ Port_D, 5 },{ Port_D, 5 } },
/* Pin 21*/{ { Port_D, 6 },{ Port_D, 6 },{ Port_D, 6 } },
/* Pin 22*/{ { Port_C, 1 },{ Port_C, 1 },{ Port_C, 1 } },
/* Pin 23*/{ { Port_C, 2 },{ Port_C, 2 },{ Port_C, 2 } },
/* Pin 24*/{ { Port_E, 20 },{ Port_A, 5 },{ Port_E, 26 } },
/* Pin 25*/{ { Port_E, 21 },{ Port_B, 19 },{ Port_A, 5 } },
/* Pin 26*/{ { Port_E, 30 },{ Port_E, 1 },{ Port_A, 14 } },
/* Pin 27*/{ { na, -1 },{ Port_C, 9 },{ Port_A, 15 } },
/* Pin 28*/{ { na, -1 },{ Port_C, 8 },{ Port_A, 16 } },
/* Pin 29*/{ { na, -1 },{ Port_C, 10 },{ Port_B, 18 } },
/* Pin 30*/{ { na, -1 },{ Port_C, 5 },{ Port_B, 19 } },
/* Pin 31*/{ { na, -1 },{ Port_E, 6 },{ Port_B, 10 } },
/* Pin 32*/{ { na, -1 },{ Port_B, 1 },{ Port_B, 11 } },
/* Pin 33*/{ { na, -1 },{ Port_A, 2 },{ Port_E, 24 } },
/* Pin 34*/{ { na, -1 },{ na, -1 },{ Port_E, 25 } },
/* Pin 35*/{ { na, -1 },{ na, -1 },{ Port_C, 8 } },
/* Pin 36*/{ { na, -1 },{ na, -1 },{ Port_C, 9 } },
/* Pin 37*/{ { na, -1 },{ na, -1 },{ Port_C, 10 } },
/* Pin 38*/{ { na, -1 },{ na, -1 },{ Port_C, 11 } },
/* Pin 39*/{ { na, -1 },{ na, -1 },{ Port_A, 17 } },
/* Pin 40*/{ { na, -1 },{ na, -1 },{ Port_A, 28 } },
/* Pin 41*/{ { na, -1 },{ na, -1 },{ Port_A, 29 } },
/* Pin 42*/{ { na, -1 },{ na, -1 },{ Port_A, 26 } },
/* Pin 43*/{ { na, -1 },{ na, -1 },{ Port_B, 20 } },
/* Pin 44*/{ { na, -1 },{ na, -1 },{ Port_B, 22 } },
/* Pin 45*/{ { na, -1 },{ na, -1 },{ Port_B, 23 } },
/* Pin 46*/{ { na, -1 },{ na, -1 },{ Port_B, 21 } },
/* Pin 47*/{ { na, -1 },{ na, -1 },{ Port_D, 8 } },
/* Pin 48*/{ { na, -1 },{ na, -1 },{ Port_D, 9 } },
/* Pin 49*/{ { na, -1 },{ na, -1 },{ Port_B, 4 } },
/* Pin 50*/{ { na, -1 },{ na, -1 },{ Port_B, 5 } },
/* Pin 51*/{ { na, -1 },{ na, -1 },{ Port_D, 14 } },
/* Pin 52*/{ { na, -1 },{ na, -1 },{ Port_D, 13 } },
/* Pin 53*/{ { na, -1 },{ na, -1 },{ Port_D, 12 } },
/* Pin 54*/{ { na, -1 },{ na, -1 },{ Port_D, 15 } },
/* Pin 55*/{ { na, -1 },{ na, -1 },{ Port_D, 11 } },
/* Pin 56*/{ { na, -1 },{ na, -1 },{ Port_E, 10 } },
/* Pin 57*/{ { na, -1 },{ na, -1 },{ Port_E, 11 } },
/* Pin 58*/{ { na, -1 },{ na, -1 },{ Port_E, 0 } },
/* Pin 59*/{ { na, -1 },{ na, -1 },{ Port_E, 1 } },
/* Pin 60*/{ { na, -1 },{ na, -1 },{ Port_E, 2 } },
/* Pin 61*/{ { na, -1 },{ na, -1 },{ Port_E, 3 } },
/* Pin 62*/{ { na, -1 },{ na, -1 },{ Port_E, 4 } },
/* Pin 63*/{ { na, -1 },{ na, -1 },{ Port_E, 5 } },
};
}
// Pin Mux constants
enum pinMux
{
ALT0 = 0,
ALT1, ALT2, ALT3, ALT4, ALT5, ALT6, ALT7
};
//-----------------------------------------------------------------------------------------------------
// Pin class
// all methods static, no instances will be generated in code
template <unsigned pinNr>
class pin
{
private:
// Calculate the adress of the pin control register
static constexpr uintptr_t get_PORTx_PCRn_addr()
{
static_assert(pinMap[pinNr][board].port != na && pinMap[pinNr][board].pin != -1, "Pin not supported by board");
return PORTx_PCR0[(pinMap[pinNr][board]).port] + 4 * pinMap[pinNr][board].pin;
}
// Calculate the adress of the bit banded GPIO registers of the pin
static constexpr uintptr_t getPDORAdr()
{
return 0x42000000 + 32 * (GPIOx_PDOR[pinMap[pinNr][board].port] - 0x40000000) + 4 * pinMap[pinNr][board].pin;
}
static constexpr uintptr_t pcr = get_PORTx_PCRn_addr(); // Pin Control Register
static constexpr uintptr_t pdorBB = getPDORAdr(); // Bitband adress of GPIOx_PDOR
static constexpr uintptr_t psorBB = pdorBB + 4 * 32; // GPIOx_PSOR = GPIOx_PDOR + 4
static constexpr uintptr_t pcorBB = psorBB + 4 * 32; // GPIOx_PCOR = GPIOx_PDOR + 8
static constexpr uintptr_t ptorBB = pcorBB + 4 * 32; // GPIOx_PTOR = GPIOx_PDOR + 12
static constexpr uintptr_t pdirBB = ptorBB + 4 * 32; // GPIOx_PDIR = GPIOx_PDOR + 16
static constexpr uintptr_t pddrBB = pdirBB + 4 * 32; // GPIOx_PDDR = GPIOx_PDOR + 20
public:
// Construction (class contains only static members)
pin() {}
pin(int i) { pinMode(i); }
pin(const pin&) = delete; // disable copy constructor
// Setting and getting the pin value
template<class T, typename = typename std::enable_if<std::is_integral<T>::value>::type>
operator T() const { return *reinterpret_cast<volatile uint32_t*>(pdirBB); }
operator bool() const { return *reinterpret_cast<volatile uint32_t*>(pdirBB) & 1; }
inline void operator = (const bool v) const { *reinterpret_cast<volatile uint32_t*>(pdorBB) = v; } // assignment --> somePin = HIGH
inline void operator = (const pin& v) const = delete; // disable copying
// Pin operations
static inline void toggle() { *reinterpret_cast<volatile uint32_t*>(ptorBB) = 1; } // toggles pin
//static inline int getValue() { return *reinterpret_cast<volatile uint32_t*>(pdirBB); } // returns pin value (usefull for static calls)
//static inline void setValue(const int v) { *reinterpret_cast<volatile uint32_t*>(pdorBB) = v; } // sets value (usefull for static calls)
//static inline void setHIGH() { *reinterpret_cast<volatile uint32_t*>(psorBB) = 1; } // sets pin to HIGH (usefull for static calls)
//static inline void setLOW() { *reinterpret_cast<volatile uint32_t*>(pcorBB) = 1; } // sets pin to LOW (usefull for static calls)
// Pin configuration
static inline void pinMode(int mode)
{
// replace by a call to pinMode(pinNr,mode) ??? TBD
switch (mode)
{
case OUTPUT:
*reinterpret_cast<volatile uint32_t*>(pddrBB) = 1; //Pin direction register
*reinterpret_cast<volatile uint32_t*>(pcr) = PORT_PCR_SRE | PORT_PCR_DSE | PORT_PCR_MUX(1); //Pin control register
break;
case OUTPUT_OPENDRAIN:
*reinterpret_cast<volatile uint32_t*>(pddrBB) = 1;
*reinterpret_cast<volatile uint32_t*>(pcr) = PORT_PCR_SRE | PORT_PCR_DSE | PORT_PCR_MUX(1) | PORT_PCR_ODE;
break;
case INPUT:
*reinterpret_cast<volatile uint32_t*>(pddrBB) = 0;
*reinterpret_cast<volatile uint32_t*>(pcr) = PORT_PCR_MUX(1);
break;
case INPUT_PULLUP:
*reinterpret_cast<volatile uint32_t*>(pddrBB) = 0;
*reinterpret_cast<volatile uint32_t*>(pcr) = PORT_PCR_MUX(1) | PORT_PCR_PE | PORT_PCR_PS;
break;
case INPUT_PULLDOWN:
*reinterpret_cast<volatile uint32_t*>(pddrBB) = 0;
*reinterpret_cast<volatile uint32_t*>(pcr) = PORT_PCR_MUX(1) | PORT_PCR_PE;
break;
case INPUT_DISABLE:
*reinterpret_cast<volatile uint32_t*>(pcr) = 0;
break;
}
}
static inline void driveStrengthEnable(bool enable)
{
//TBD static_assert: pin has DSE capability
if (enable) {
*reinterpret_cast<uint32_t*>(pcr) |= PORT_PCR_DSE;
}
else {
*reinterpret_cast<uint32_t*>(pcr) &= ~PORT_PCR_DSE;
}
}
static inline void slowSlewRateEnable(bool enable)
{
//TBD static_assert: pin has SRE capability
if (enable) {
*reinterpret_cast<uint32_t*>(pcr) |= PORT_PCR_SRE;
}
else {
*reinterpret_cast<uint32_t*>(pcr) &= ~PORT_PCR_SRE;
}
}
static inline void setMUX(pinMux altFunc)
{
*reinterpret_cast<uint32_t*>(pcr) = (*reinterpret_cast<uint32_t*>(pcr) & ~PORT_PCR_MUX_MASK) | PORT_PCR_MUX(altFunc);
}
static inline void attachInterrupt(void(*function)(void), int mode)
{
::attachInterrupt(pinNr, function, mode);
}
};
}

@ -0,0 +1,38 @@
#include "ResponsiveAnalogRead.h"
#include "SystemController.h"
constexpr unsigned potPin = A0;
ResponsiveAnalogRead pot(potPin, false);
SystemController sysControl;
void setup()
{
sysControl.begin();
sysControl.setExposureDelay(250); // set exposure delay (time between two exposures) to 250 µs
sysControl.shoot(); // do a manual exposure
delay(10);
sysControl.setExposureDelay(500); // same with 500µs delay between exposures
sysControl.shoot();
sysControl.continousMode(true); // start continously shooting
delay(1000);
sysControl.continousMode(false); // stop after one second
delay(500);
sysControl.continousMode(true); // start again
}
void loop()
{
// --> Uncomment if you have a control voltage on the pot pin <--
// pot.update();
// if (pot.hasChanged())
// {
// unsigned expDelay = map(pot.getValue(), 0, 1023, 100, 500); // 0-3.3V analog value, maps to 100-500
// controller.setExposureDelay(expDelay);
// Serial.printf("Exposure Delay: %u µs\n", expDelay);
// }
}

@ -0,0 +1,32 @@
#pragma once
#include "PulseGenerator.h"
#include "TeensyTimerTool.h"
class LaserController
{
public:
void begin(unsigned preTriggerPin, unsigned triggerPin, unsigned camPin);
void shoot();
protected:
PulseGenerator preTrigger, trigger, camera;
};
void LaserController::begin(unsigned preTriggerPin, unsigned triggerPin, unsigned camPin)
{
preTrigger.begin(preTriggerPin);
trigger.begin(triggerPin);
camera.begin(camPin);
}
void LaserController::shoot()
{
constexpr float t_warmup = 140 - 5.5;
constexpr float t_p = 10 - 3;
constexpr float t_camDelay = 130 - 7.5;
constexpr float t_int = 30 - 3;
preTrigger.schedulePulse(0, t_p); // immediately generate the pretrigger pulse
trigger.schedulePulse(t_warmup, t_p); // schedule the trigger pulse to start after the warmup time
camera.schedulePulse(t_camDelay, t_int); // schedule the cam pulse after the camDelay time
}

@ -0,0 +1,61 @@
#pragma once
#include "Arduino.h"
#include "TeensyTimerTool.h"
class PulseGenerator
{
public:
PulseGenerator(); // constructor, initializes non hardware related stuff
void begin(unsigned pin); // intializes hardware related stuff
void schedulePulse(float delay, float width); // schedules a 'width µs' wide pulse after a waiting time of 'delay µs'. Non blocking.
protected:
TeensyTimerTool::OneShotTimer pulseTimer; // used for generating the pulses
void callback();
uint32_t pin;
float width;
};
void PulseGenerator::begin(unsigned pin)
{
this->pin = pin;
pinMode(pin, OUTPUT);
digitalWriteFast(pin, LOW);
pulseTimer.begin([this] { this->callback(); });
}
void PulseGenerator::schedulePulse(float delay, float _width)
{
width = _width; // the timer callback needs to know the pulse width to generate the pulse
if (delay != 0)
{
pulseTimer.trigger(delay); // this triggers the oneShot timer to fire after 'delay µs'
}
else //delay == 0, directly generate the pulse
{
digitalWriteFast(pin, HIGH);
pulseTimer.trigger(width); // this triggers the oneShotTimer to fire after 'width µs'
}
}
void PulseGenerator::callback()
{
if (digitalReadFast(pin) == LOW)
{
digitalWriteFast(pin, HIGH);
pulseTimer.trigger(width); // retrigger
} else
{
digitalWriteFast(pin, LOW);
}
}
PulseGenerator::PulseGenerator()
: pulseTimer(TeensyTimerTool::FTM0) // use one of the 8 FTM0 channels
{}

@ -0,0 +1 @@
### See https://github.com/luni64/TeensyTimerTool/wiki/Double-Exposure-Laser-Illuminator for a description of this example.

@ -0,0 +1,63 @@
#pragma once
#include "LaserController.h"
#include "TeensyTimerTool.h"
class SystemController
{
public:
SystemController();
inline void begin();
inline void shoot();
inline void continousMode(bool on);
inline void setExposureDelay(unsigned delay);
protected:
TeensyTimerTool::PeriodicTimer mainTimer;
LaserController lCtrl1, lCtrl2;
unsigned exposureDelay = 300;
};
SystemController::SystemController()
: mainTimer(TeensyTimerTool::TCK) {} // construct the main 15Hz timer, we use a TCK here
void SystemController::begin()
{
constexpr unsigned repetitionRate = 15; // Hz
constexpr unsigned preTrig1_pin = 1;
constexpr unsigned trig1_pin = 2;
constexpr unsigned preTrig2_pin = 3;
constexpr unsigned trig2_pin = 4;
constexpr unsigned cam_pin = 5;
lCtrl1.begin(preTrig1_pin, trig1_pin, cam_pin);
lCtrl2.begin(preTrig2_pin, trig2_pin, cam_pin);
mainTimer.begin([this] { this->shoot(); }, 1E6 / repetitionRate, false); // attach callback but don't start yet
}
void SystemController::shoot()
{
elapsedMicros stopwatch = 0;
lCtrl1.shoot();
while (stopwatch < exposureDelay) { yield(); }
lCtrl2.shoot();
}
void SystemController::continousMode(bool on)
{
if (on)
{
mainTimer.start();
}
else
{
mainTimer.stop();
}
}
void SystemController::setExposureDelay(unsigned delay)
{
exposureDelay = max(100u, min(500u, delay)); // limit to 100-500 µs
}

@ -0,0 +1,39 @@
#pragma once
#include "core_pins.h"
#include <cstdint>
struct GPIO_Info_t
{
inline GPIO_Info_t(unsigned pin);
const uintptr_t pinCfg;
const unsigned gpioPortNr;
const unsigned gpioBitNr;
char name[20];
};
//======================================================================================
#if defined(KINETISK) || defined(KINETISL)
GPIO_Info_t::GPIO_Info_t(unsigned pin)
: pinCfg((uintptr_t)digital_pin_to_info_PGM[pin].config), // address of pin config register
gpioPortNr((pinCfg - (uintptr_t)&PORTA_PCR0) / 0x1000), // cfg base addresses are 4kB aligned staring with PORTA_PCR0
gpioBitNr((pinCfg & 0xFFF) / 4) // each bit has to 4 consecutive 32bit cfg registers
{
snprintf(name, 20, "GPIO%d_%02d", gpioPortNr, gpioBitNr);
}
//======================================================================================
#elif defined(ARDUINO_TEENSY40) || defined(ARDUINO_TEENSY41)
GPIO_Info_t::GPIO_Info_t(unsigned pin)
: pinCfg((uintptr_t)digital_pin_to_info_PGM[pin].reg), // address of pin config register
gpioPortNr((pinCfg - (uintptr_t)&IMXRT_GPIO6) / 0x4000 + 6), // cfg base addresses are 4kB aligned staring with PORTA_PCR0
gpioBitNr(__builtin_ffs(digital_pin_to_info_PGM[pin].mask) - 1) // each bit has to 4 consecutive 32bit cfg registers
{
snprintf(name, 20, "GPIO%d_%02d", gpioPortNr, gpioBitNr);
}
#endif

@ -0,0 +1,213 @@
#include "core_pins.h"
/*****
* Unlike Teensy 4.x there is no information array in the core for the T3.x series
* We thus build the corresponding array from copies of the pin definitions in core_pins.h
*****/
#if defined(ARDUINO_TEENSYLC)
const int PwmTimerModule[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = -1,
[CORE_TPM0_CH0_PIN] = 0,
[CORE_TPM0_CH1_PIN] = 0,
[CORE_TPM0_CH2_PIN] = 0,
[CORE_TPM0_CH3_PIN] = 0,
[CORE_TPM0_CH4_PIN] = 0,
[CORE_TPM0_CH5_PIN] = 0,
[CORE_TPM1_CH0_PIN] = 1,
[CORE_TPM1_CH1_PIN] = 1,
[CORE_TPM2_CH0_PIN] = 2,
[CORE_TPM2_CH1_PIN] = 2,
};
const int PwmTimerType[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = 0,
[CORE_TPM0_CH0_PIN] = 2,
[CORE_TPM0_CH1_PIN] = 2,
[CORE_TPM0_CH2_PIN] = 2,
[CORE_TPM0_CH3_PIN] = 2,
[CORE_TPM0_CH4_PIN] = 2,
[CORE_TPM0_CH5_PIN] = 2,
[CORE_TPM1_CH0_PIN] = 2,
[CORE_TPM1_CH1_PIN] = 2,
[CORE_TPM2_CH0_PIN] = 2,
[CORE_TPM2_CH1_PIN] = 2,
};
//===========================================================================================
#elif defined(ARDUINO_TEENSY30)
const int PwmTimerModule[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = -1,
[CORE_FTM0_CH0_PIN] = 0,
[CORE_FTM0_CH1_PIN] = 0,
[CORE_FTM0_CH2_PIN] = 0,
[CORE_FTM0_CH3_PIN] = 0,
[CORE_FTM0_CH4_PIN] = 0,
[CORE_FTM0_CH5_PIN] = 0,
[CORE_FTM0_CH6_PIN] = 0,
[CORE_FTM0_CH7_PIN] = 0,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
};
const int PwmTimerType[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = 0,
[CORE_FTM0_CH0_PIN] = 1,
[CORE_FTM0_CH1_PIN] = 1,
[CORE_FTM0_CH2_PIN] = 1,
[CORE_FTM0_CH3_PIN] = 1,
[CORE_FTM0_CH4_PIN] = 1,
[CORE_FTM0_CH5_PIN] = 1,
[CORE_FTM0_CH6_PIN] = 1,
[CORE_FTM0_CH7_PIN] = 1,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
};
//===========================================================================================
#elif defined(__MK20DX256__)
const int PwmTimerModule[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = -1,
[CORE_FTM0_CH0_PIN] = 0,
[CORE_FTM0_CH1_PIN] = 0,
[CORE_FTM0_CH0_PIN] = 0,
[CORE_FTM0_CH1_PIN] = 0,
[CORE_FTM0_CH2_PIN] = 0,
[CORE_FTM0_CH3_PIN] = 0,
[CORE_FTM0_CH4_PIN] = 0,
[CORE_FTM0_CH5_PIN] = 0,
[CORE_FTM0_CH6_PIN] = 0,
[CORE_FTM0_CH7_PIN] = 0,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 2,
[CORE_FTM2_CH1_PIN] = 2,
};
//===========================================================================================
const int PwmTimerType[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = 0,
[CORE_FTM0_CH0_PIN] = 1,
[CORE_FTM0_CH1_PIN] = 1,
[CORE_FTM0_CH0_PIN] = 1,
[CORE_FTM0_CH1_PIN] = 1,
[CORE_FTM0_CH2_PIN] = 1,
[CORE_FTM0_CH3_PIN] = 1,
[CORE_FTM0_CH4_PIN] = 1,
[CORE_FTM0_CH5_PIN] = 1,
[CORE_FTM0_CH6_PIN] = 1,
[CORE_FTM0_CH7_PIN] = 1,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 1,
[CORE_FTM2_CH1_PIN] = 1,
};
//===========================================================================================
#elif defined(ARDUINO_TEENSY35)
const int PwmTimerModule[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = -1,
[CORE_FTM0_CH0_PIN] = 0,
[CORE_FTM0_CH1_PIN] = 0,
[CORE_FTM0_CH2_PIN] = 0,
[CORE_FTM0_CH3_PIN] = 0,
[CORE_FTM0_CH4_PIN] = 0,
[CORE_FTM0_CH5_PIN] = 0,
[CORE_FTM0_CH6_PIN] = 0,
[CORE_FTM0_CH7_PIN] = 0,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 2,
[CORE_FTM2_CH1_PIN] = 2,
[CORE_FTM3_CH0_PIN] = 3,
[CORE_FTM3_CH1_PIN] = 3,
[CORE_FTM3_CH2_PIN] = 3,
[CORE_FTM3_CH3_PIN] = 3,
[CORE_FTM3_CH4_PIN] = 3,
[CORE_FTM3_CH5_PIN] = 3,
[CORE_FTM3_CH6_PIN] = 3,
[CORE_FTM3_CH7_PIN] = 3,
};
const int PwmTimerType[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = 0,
[CORE_FTM0_CH0_PIN] = 1,
[CORE_FTM0_CH1_PIN] = 1,
[CORE_FTM0_CH2_PIN] = 1,
[CORE_FTM0_CH3_PIN] = 1,
[CORE_FTM0_CH4_PIN] = 1,
[CORE_FTM0_CH5_PIN] = 1,
[CORE_FTM0_CH6_PIN] = 1,
[CORE_FTM0_CH7_PIN] = 1,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 1,
[CORE_FTM2_CH1_PIN] = 1,
[CORE_FTM3_CH0_PIN] = 1,
[CORE_FTM3_CH1_PIN] = 1,
[CORE_FTM3_CH2_PIN] = 1,
[CORE_FTM3_CH3_PIN] = 1,
[CORE_FTM3_CH4_PIN] = 1,
[CORE_FTM3_CH5_PIN] = 1,
[CORE_FTM3_CH6_PIN] = 1,
[CORE_FTM3_CH7_PIN] = 1,
};
//===========================================================================================
#elif defined(ARDUINO_TEENSY36)
const int PwmTimerModule[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = -1,
[CORE_FTM0_CH0_PIN] = 0,
[CORE_FTM0_CH1_PIN] = 0,
[CORE_FTM0_CH2_PIN] = 0,
[CORE_FTM0_CH3_PIN] = 0,
[CORE_FTM0_CH4_PIN] = 0,
[CORE_FTM0_CH5_PIN] = 0,
[CORE_FTM0_CH6_PIN] = 0,
[CORE_FTM0_CH7_PIN] = 0,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 2,
[CORE_FTM2_CH1_PIN] = 2,
[CORE_FTM3_CH0_PIN] = 3,
[CORE_FTM3_CH1_PIN] = 3,
[CORE_FTM3_CH2_PIN] = 3,
[CORE_FTM3_CH3_PIN] = 3,
[CORE_FTM3_CH4_PIN] = 3,
[CORE_FTM3_CH5_PIN] = 3,
[CORE_FTM3_CH6_PIN] = 3,
[CORE_FTM3_CH7_PIN] = 3,
[CORE_TPM1_CH0_PIN] = 1,
[CORE_TPM1_CH1_PIN] = 1,
};
const int PwmTimerType[CORE_NUM_DIGITAL] = {
[0 ... CORE_NUM_DIGITAL - 1] = 0,
[CORE_FTM0_CH0_PIN] = 1,
[CORE_FTM0_CH1_PIN] = 1,
[CORE_FTM0_CH2_PIN] = 1,
[CORE_FTM0_CH3_PIN] = 1,
[CORE_FTM0_CH4_PIN] = 1,
[CORE_FTM0_CH5_PIN] = 1,
[CORE_FTM0_CH6_PIN] = 1,
[CORE_FTM0_CH7_PIN] = 1,
[CORE_FTM1_CH0_PIN] = 1,
[CORE_FTM1_CH1_PIN] = 1,
[CORE_FTM2_CH0_PIN] = 1,
[CORE_FTM2_CH1_PIN] = 1,
[CORE_FTM3_CH0_PIN] = 1,
[CORE_FTM3_CH1_PIN] = 1,
[CORE_FTM3_CH2_PIN] = 1,
[CORE_FTM3_CH3_PIN] = 1,
[CORE_FTM3_CH4_PIN] = 1,
[CORE_FTM3_CH5_PIN] = 1,
[CORE_FTM3_CH6_PIN] = 1,
[CORE_FTM3_CH7_PIN] = 1,
[CORE_TPM1_CH0_PIN] = 2,
[CORE_TPM1_CH1_PIN] = 2,
};
#endif

@ -0,0 +1,62 @@
#pragma once
#include "core_pins.h"
#include <cstdio>
struct PWM_TimerInfo_t
{
inline PWM_TimerInfo_t(unsigned _pin = 0);
unsigned type;
unsigned module;
char name[20];
};
//===========================================================================================================
#if defined(ARDUINO_TEENSY40) || defined(ARDUINO_TEENSY41)
// holds core info about used pwm timers. Struct is defined in pwm.c.
// There is no header declaring it. So, we need to do this here:
struct pwm_pin_info_struct
{
uint8_t type; // 0=no pwm, 1=flexpwm, 2=quad
uint8_t module; // 0-3, 0-3
uint8_t channel; // 0=X, 1=A, 2=B
uint8_t muxval; //
};
extern pwm_pin_info_struct pwm_pin_info[]; // This array holds the pwm timer info
PWM_TimerInfo_t::PWM_TimerInfo_t(unsigned pin)
{
constexpr char timerNames[][9] = {"FLEX_PWM", "QUAD"};
type = pwm_pin_info[pin].type;
module = (pwm_pin_info[pin].module >> 4) + 1;
if (type != 0)
snprintf(name, 20, "%s%d", timerNames[type - 1], module);
else
snprintf(name, 20, "no pwm");
}
//===========================================================================================================
#elif defined(ARDUINO_TEENSYLC) || \
defined(ARDUINO_TEENSY30) || defined(ARDUINO_TEENSY32) || \
defined(ARDUINO_TEENSY35) || defined(ARDUINO_TEENSY36)
extern "C" const int PwmTimerModule[CORE_NUM_DIGITAL];
extern "C" const int PwmTimerType[CORE_NUM_DIGITAL];
PWM_TimerInfo_t::PWM_TimerInfo_t(unsigned pin)
{
constexpr char timerNames[][9] = {"FTM", "TPM"};
type = PwmTimerType[pin];
module = PwmTimerModule[pin];
if (type != 0)
snprintf(name, 20, "%s%d", timerNames[type - 1], module);
else
snprintf(name, 20, "none");
}
#endif

@ -0,0 +1,17 @@
#pragma once
#include "GPIO_Info.h"
#include "PWM_TimerInfo.h"
struct PinInfo
{
inline PinInfo(unsigned _pin)
: pin(_pin),
gpioInfo(pin),
pwmTimerInfo(pin)
{}
const unsigned pin;
const GPIO_Info_t gpioInfo;
const PWM_TimerInfo_t pwmTimerInfo;
};

@ -0,0 +1,53 @@
#include "PinInfo.h"
#include <algorithm>
void setup()
{
while (!Serial) {}
// setup an array containing info for all digital pins
PinInfo* pins[CORE_NUM_DIGITAL];
for (unsigned i = 0; i < CORE_NUM_DIGITAL; i++)
{
pins[i] = new PinInfo(i);
}
// Print out info sorted by pin numbers
Serial.println("-------------------------------");
Serial.println(" Sorted by pin number");
printPins(pins, CORE_NUM_DIGITAL);
Serial.println("\n-------------------------------");
Serial.println(" Sorted by PWM timer");
std::sort(pins, pins + CORE_NUM_DIGITAL, [](PinInfo* a, PinInfo* b) {
if (a->pwmTimerInfo.type < b->pwmTimerInfo.type) return false;
if (a->pwmTimerInfo.type > b->pwmTimerInfo.type) return true;
if (a->pwmTimerInfo.module < b->pwmTimerInfo.module) return true;
return false;
});
printPins(pins, CORE_NUM_DIGITAL);
Serial.println("\n-------------------------------");
Serial.println(" Sorted by GPIO register: ");
std::sort(pins, pins + CORE_NUM_DIGITAL, [](PinInfo* a, PinInfo* b) {
if (a->gpioInfo.gpioPortNr < b->gpioInfo.gpioPortNr) return true;
if (a->gpioInfo.gpioPortNr > b->gpioInfo.gpioPortNr) return false;
if (a->gpioInfo.gpioBitNr < b->gpioInfo.gpioBitNr) return true;
return false;
});
printPins(pins, CORE_NUM_DIGITAL);
}
void loop() {}
// Helpers -------------------------------------------------------
void printPins(PinInfo* pins[], unsigned nrOfPins)
{
Serial.println("Pin | GPIO Reg | PWM timer");
Serial.println("----|------------|-------------");
for (unsigned i = 0; i < nrOfPins; i++)
{
Serial.printf("%02d | %-9s | %-10s\n", pins[i]->pin, pins[i]->gpioInfo.name, pins[i]->pwmTimerInfo.name);
}
}

@ -0,0 +1,21 @@
{
"name": "TeensyTimerTool",
"keywords": "teensy, pjrc, timer, quad, gpt, tmr, pit, imxrt1062",
"description": "TeensyTimerTool is a library that provides a generic, easy to use interface to the hardware timers of the PJRC Teensy boards. In addition, it provides up to 20 highly efficient software timers that use the same interface. All timers can be used in periodic and one-shot mode. Currently the library supports the ARM T3.X and T4.0 boards. You can either pick a free timer from a pool or specify exactly which of the available hardware or software timer modules you want to use.",
"repository":
{
"type": "git",
"url": "https://github.com/luni64/TeensyTimerTool"
},
"authors":
{
"name": "Lutz Niggl",
"email": "lutz.niggl@lunoptics.com",
"url": "https://github.com/luni64",
"maintainer": true
},
"homepage": "https://github.com/luni64/TeensyTimerTool",
"version": "0.3.3",
"frameworks": "arduino",
"platforms": "Teensy"
}

@ -0,0 +1,10 @@
name=TeensyTimerTool
version=0.3.3
author=Lutz Niggl <lutz.niggl@lunoptics.com>
maintainer=Lutz Niggl <lutz.niggl@lunoptics.com>
sentence=Generic Interface to Teensy Timers
paragraph= TeensyTimerTool is a library that provides a generic, easy to use interface to the hardware timers (FTM, GPT, QUAD, PIT) of the PJRC Teensy boards. In addition, it provides up to 20 highly efficient software timers that use the same interface. All timers can be used in periodic and one-shot mode. Currently the library supports the ARM T3.X and T4.0 boards. You can either pick a free timer from a pool or specify exactly which of the available hardware or software timer modules you want to use.
category=Timing
url=https://github.com/luni64/TeensyTimerTool
architectures=*
includes=TeensyTimerTool.h

@ -0,0 +1,17 @@
#ifdef ESP32
#include "../../TeensyTimerTool.h"
#if defined(HAS_TCK) and defined(ESP32)
namespace TeensyTimerTool
{
bool TCK_t::isInitialized = false;
TckChannel* TCK_t::channels[maxTckChannels];
}
void yield() { TeensyTimerTool::TCK_t::tick(); }
#endif
#endif

@ -0,0 +1,79 @@
#pragma once
#include "TckChannel.h"
#include <Arduino.h>
#include <cstdint>
namespace TeensyTimerTool
{
constexpr unsigned maxTckChannels = 20;
class TCK_t
{
public:
static inline ITimerChannel* getTimer();
static inline void removeTimer(TckChannel*);
static inline void tick();
protected:
static bool isInitialized;
static TckChannel* channels[maxTckChannels];
};
// IMPLEMENTATION ==================================================================
ITimerChannel* TCK_t::getTimer()
{
Serial.printf("TCK getTimer()\n");
if (!isInitialized)
{
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
channels[chNr] = nullptr;
}
isInitialized = true;
}
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
if (channels[chNr] == nullptr)
{
channels[chNr] = new TckChannel();
return channels[chNr];
}
}
return nullptr;
}
void TCK_t::removeTimer(TckChannel* channel)
{
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
if (channels[chNr] == channel)
{
channels[chNr] = nullptr;
delete channel;
break;
}
}
}
void TCK_t::tick()
{
digitalWriteFast(12,HIGH);
for(unsigned i = 0; i < maxTckChannels; i++)
{
if (channels[i] != nullptr )
{
channels[i]->tick();
}
}
digitalWriteFast(12,LOW);
}
constexpr TimerGenerator* TCK = TCK_t::getTimer;
} // namespace TeensyTimerTool

@ -0,0 +1,89 @@
#pragma once
#include "../ITimerChannel.h"
#include "../types.h"
#include "Arduino.h"
namespace TeensyTimerTool
{
class TCK_t;
class TckChannel : public ITimerChannel
{
public:
inline TckChannel() { triggered = false; }
inline virtual ~TckChannel(){};
inline void begin(callback_t cb, unsigned period, bool periodic)
{
Serial.println("begin");
triggered = false;
this->periodic = periodic;
this->period = period * (F_CPU / 1'000'000);
this->callback = cb;
startCNT = ARM_DWT_CYCCNT;
}
inline void start()
{
Serial.println("start");
this->startCNT = ARM_DWT_CYCCNT;
this->triggered = true;
}
inline void stop()
{
this->triggered = false;
}
// inline void setPeriod(uint32_t microSeconds);
inline uint32_t getPeriod(void);
inline void trigger(uint32_t delay) // µs
{
this->startCNT = ARM_DWT_CYCCNT;
this->period = delay * (F_CPU / 1'000'000) - 68;
this->triggered = true;
}
protected:
uint32_t startCNT, period;
callback_t callback;
bool triggered;
bool periodic;
inline void tick();
bool block = false;
friend TCK_t;
};
// IMPLEMENTATION ==============================================
void TckChannel::tick()
{
static bool lock = false;
if (!lock && period != 0 && triggered && (ARM_DWT_CYCCNT - startCNT) >= period)
{
lock = true;
startCNT = ARM_DWT_CYCCNT;
triggered = periodic; // i.e., stays triggerd if periodic, stops if oneShot
callback();
lock = false;
}
}
// void TckChannel::setPeriod(uint32_t microSeconds)
// {
// period = microSeconds * (F_CPU / 1'000'000) ;
// }
uint32_t TckChannel::getPeriod()
{
return period * (1'000'000.0f / F_CPU);
}
} // namespace TeensyTimerTool

@ -0,0 +1,40 @@
#pragma once
namespace TeensyTimerTool
{
enum class errorCode
{
OK = 0,
// Warnings
periodOverflow= -100,
wrongType= -101,
triggeredLate= -102, //warn if new setted period is shorter than elapsed time
//General errors
argument = 100,
callback= 101,
reload= 102,
noFreeModule = 103,
noFreeChannel = 104, // requested module has no free channel
notImplemented= 105, // timer does not support this feature
notInitialized= 106,
// GTP Errors
GTP_err = 200,
GTP_err2 = 201,
//TMR Errors
TMR_err = 300,
TMR_err2 = 301,
//FTM Errors
FTM_err = 400,
FTM_err2 = 401,
//TCK Errors
TCK_err = 900,
TCK_err2 = 901,
};
}

@ -0,0 +1,79 @@
#include "error_handler.h"
#include "core_pins.h"
#include "types.h"
namespace TeensyTimerTool
{
ErrorHandler::ErrorHandler(Stream& s) : stream(s)
{
pinMode(LED_BUILTIN, OUTPUT);
}
void ErrorHandler::operator()(errorCode code) const
{
const char* txt;
switch (code)
{
case errorCode::OK:
txt = "OK";
break;
// warnings
case errorCode::periodOverflow:
txt = "Period overflow, set to maximum";
break;
case errorCode::wrongType:
txt = "Wrong parameter type";
break;
// general errors
case errorCode::reload:
txt = "Period must not be zero";
break;
case errorCode::noFreeChannel:
txt = "Timer module has no free channel";
break;
case errorCode::noFreeModule:
txt = "Timer pool contains no free timer";
break;
case errorCode::notImplemented:
txt = "Function not implemented for this timer";
break;
case errorCode::notInitialized:
txt = "Timer not initialized or available";
break;
default:
txt = "Unknown error";
break;
}
if ((int)code < 0) // in case of warnings we return after printing
{
stream.printf("W-%i: %s\n", -(int)code, txt);
return;
}
stream.printf("E-%i: %s\n", (int)code, txt); // in case of errors we don't return
while (true)
{
digitalWriteFast(LED_BUILTIN, !digitalReadFast(LED_BUILTIN));
delay(50);
}
}
errorFunc_t errFunc;
errorCode postError(errorCode e)
{
if (errFunc != nullptr && e != errorCode::OK) errFunc(e);
return e;
}
void attachErrFunc(errorFunc_t _errFunc)
{
errFunc = _errFunc;
}
}

@ -0,0 +1,17 @@
#pragma once
#include "error_codes.h"
#include "Stream.h"
namespace TeensyTimerTool
{
class ErrorHandler
{
public:
ErrorHandler(Stream& s);
void operator()(errorCode code) const;
protected:
Stream& stream;
};
}

@ -0,0 +1,48 @@
#pragma once
#include "types.h"
namespace TeensyTimerTool
{
class ITimerChannel
{
public:
virtual errorCode begin(callback_t callback, float period, bool oneShot) = 0;
virtual errorCode trigger(float delay) = 0;
virtual errorCode triggerDirect(uint32_t reload){ return postError(errorCode::notImplemented); };
virtual errorCode triggerDirect(uint64_t reload){ return postError(errorCode::notImplemented); };
virtual errorCode getTriggerReload(float delay, uint32_t* reload) {return postError(errorCode::notImplemented);};
virtual errorCode getTriggerReload(float delay, uint64_t* reload) {return postError(errorCode::notImplemented);};
virtual errorCode start() = 0;
virtual errorCode stop() = 0;
virtual errorCode setPrescaler(int psc) { return postError(errorCode::notImplemented); }
virtual float getMaxPeriod() const = 0;
//virtual errorCode setPeriod(uint32_t microSeconds) { return postError(errorCode::notImplemented); };
virtual errorCode setPeriod(float microSeconds) { return postError(errorCode::notImplemented); };
//virtual errorCode setNextPeriod(uint32_t microSeconds) { return postError(errorCode::notImplemented); };
virtual errorCode setNextPeriod(float microSeconds) { return postError(errorCode::notImplemented); };
virtual uint32_t getPeriod() { return 0; }
inline void setCallback(callback_t);
protected:
inline ITimerChannel(callback_t* cbStorage = nullptr);
callback_t* pCallback;
};
// IMPLEMENTATION ====================================================
ITimerChannel::ITimerChannel(callback_t* cbStorage)
{
this->pCallback = cbStorage;
}
void ITimerChannel::setCallback(callback_t cb)
{
*pCallback = cb;
}
} // namespace TeensyTimerTool

@ -0,0 +1,91 @@
#pragma once
#include "FTM_Channel.h"
#include "FTM_Info.h"
namespace TeensyTimerTool
{
template <unsigned moduleNr>
class FTM_t
{
public:
inline static ITimerChannel* getTimer();
FTM_t() = delete;
private:
static bool isInitialized;
inline static void isr() FASTRUN;
static constexpr FTM_r_t* r = (FTM_r_t*)FTM_Info<moduleNr>::baseAdr;
static constexpr unsigned maxChannel = FTM_Info<moduleNr>::nrOfChannels;
static FTM_ChannelInfo channelInfo[maxChannel];
static_assert(moduleNr < 4, "Module number < 4 required");
};
// IMPLEMENTATION ==================================================================
template <unsigned moduleNr>
ITimerChannel* FTM_t<moduleNr>::getTimer()
{
if (!isInitialized)
{
r->SC = FTM_SC_CLKS(0b00); // Disable clock
r->MOD = 0xFFFF; // Set full counter range
r->CNT = 0;
for (unsigned chNr = 0; chNr < maxChannel; chNr++) // init channels
{
channelInfo[chNr].isReserved = false;
channelInfo[chNr].callback = nullptr;
channelInfo[chNr].chRegs = &r->CH[chNr];
channelInfo[chNr].ticksPerMicrosecond = 1E-6f * F_BUS / (1 << FTM_Info<moduleNr>::prescale);
r->CH[chNr].SC &= ~FTM_CSC_CHF; // FTM requires to clear flag by setting bit to 0
r->CH[chNr].SC &= ~FTM_CSC_CHIE; // Disable channel interupt
r->CH[chNr].SC = FTM_CSC_MSA;
}
r->SC = FTM_SC_CLKS(0b01) | FTM_SC_PS(FTM_Info<moduleNr>::prescale); // Start clock
attachInterruptVector(FTM_Info<moduleNr>::irqNumber, isr); // prepare isr and nvic, don't yet enable interrupts
NVIC_ENABLE_IRQ(FTM_Info<moduleNr>::irqNumber);
isInitialized = true;
}
for (unsigned chNr = 0; chNr < maxChannel; chNr++)
{
if (!channelInfo[chNr].isReserved)
{
channelInfo[chNr].isReserved = true;
return new FTM_Channel(r, &channelInfo[chNr]);
}
}
return nullptr;
}
template <unsigned m>
void FTM_t<m>::isr()
{
for (unsigned i = 0; i < maxChannel; i++)
{
FTM_ChannelInfo* ci = &channelInfo[i]; // pre resolving the references turns out to be slightly faster
FTM_CH_t* cr = ci->chRegs;
if ((cr->SC & (FTM_CSC_CHIE | FTM_CSC_CHF)) == (FTM_CSC_CHIE | FTM_CSC_CHF)) // only handle if channel is active (CHIE set) and overflowed (CHF set)
{
if (ci->isPeriodic)
{
cr->SC &= ~FTM_CSC_CHF; // clear channel flag
cr->CV = r->CNT + ci->reload; // set compare value to 'reload' counts ahead of counter
} else
{
cr->SC &= ~FTM_CSC_CHIE; //disable interrupt in on shot mode
}
ci->callback();
}
}
}
template <unsigned m>
FTM_ChannelInfo FTM_t<m>::channelInfo[maxChannel];
template <unsigned m>
bool FTM_t<m>::isInitialized = false;
}

@ -0,0 +1,120 @@
#pragma once
#include "../../ITimerChannel.h"
#include "Arduino.h"
#include "FTM_ChannelInfo.h"
#include "FTM_Info.h"
namespace TeensyTimerTool
{
class FTM_Channel : public ITimerChannel
{
public:
inline FTM_Channel(FTM_r_t* regs, FTM_ChannelInfo* ci);
inline virtual ~FTM_Channel();
inline float getMaxPeriod() const override;
inline errorCode begin(callback_t cb, float tcnt, bool periodic)
{
begin(cb, (uint32_t)tcnt, periodic);
return errorCode::OK;
};
inline errorCode begin(callback_t cb, uint32_t tcnt, bool periodic);
inline errorCode trigger(float tcnt) override FASTRUN;
inline errorCode triggerDirect(uint32_t reload) override FASTRUN;
inline errorCode getTriggerReload(float delay, uint32_t* reload) override;
inline errorCode start() override;
inline errorCode stop() override;
inline uint16_t ticksFromMicros(float micros);
// inline void setPeriod(uint32_t) {}
protected:
FTM_ChannelInfo* ci;
FTM_r_t* regs;
callback_t* pCallback = nullptr;
};
// IMPLEMENTATION ==============================================
FTM_Channel::FTM_Channel(FTM_r_t* regs, FTM_ChannelInfo* channelInfo)
: ITimerChannel(nullptr)
{
this->regs = regs;
this->ci = channelInfo;
}
errorCode FTM_Channel::begin(callback_t callback, uint32_t tcnt, bool periodic)
{
ci->isPeriodic = periodic;
ci->reload = ticksFromMicros(tcnt);
ci->callback = callback;
return errorCode::OK;
}
errorCode FTM_Channel::start()
{
ci->chRegs->CV = regs->CNT + ci->reload; // compare value (current counter + pReload)
ci->chRegs->SC &= ~FTM_CSC_CHF; // reset timer flag
ci->chRegs->SC = FTM_CSC_MSA | FTM_CSC_CHIE; // enable interrupts
return errorCode::OK;
}
errorCode FTM_Channel::stop()
{
ci->chRegs->SC &= ~FTM_CSC_CHIE; // enable interrupts
ci->chRegs->SC &= ~FTM_CSC_CHF; // reset timer flag
return errorCode::OK;
}
errorCode FTM_Channel::getTriggerReload(float delay, uint32_t* reload)
{
*reload = ticksFromMicros(delay);
return errorCode::OK;
}
errorCode FTM_Channel::trigger(float delay)
{
return triggerDirect(ticksFromMicros(delay));
}
errorCode FTM_Channel::triggerDirect(uint32_t reload)
{
uint32_t cv = regs->CNT + reload + 1; // calc early to minimize error
ci->chRegs->SC &= ~FTM_CSC_CHF; // Reset timer flag
regs->SC &= ~FTM_SC_CLKS_MASK; // need to switch off clock to immediately set new CV
ci->chRegs->CV = cv; // compare value (current counter + pReload)
regs->SC |= FTM_SC_CLKS(0b01); // restart clock
ci->chRegs->SC = FTM_CSC_MSA | FTM_CSC_CHIE; // enable interrupts
return errorCode::OK;
}
float FTM_Channel::getMaxPeriod() const
{
return (0xFFFF * 1E-6f) / ci->ticksPerMicrosecond; // max period in seconds
}
uint16_t FTM_Channel::ticksFromMicros(float micros)
{
uint32_t rl = ci->ticksPerMicrosecond * micros;
if (rl > 0xFFFF)
{
postError(errorCode::periodOverflow); // warning only, continues with clipped value
rl = 0xFFFF;
}
return rl;
}
FTM_Channel::~FTM_Channel()
{
}
} // namespace TeensyTimerTool

@ -0,0 +1,17 @@
#pragma once
#include "FTM_Info.h"
#include "../../types.h"
namespace TeensyTimerTool
{
struct FTM_ChannelInfo
{
bool isReserved;
bool isPeriodic;
callback_t callback;
uint32_t reload;
FTM_CH_t* chRegs;
float ticksPerMicrosecond;
};
}

@ -0,0 +1,110 @@
#pragma once
#include "boardDef.h"
#include <algorithm>
// All information in this header is calculated at compile time.
// FTM_Info will not generate any code
namespace TeensyTimerTool
{
typedef struct // FTM & TPM Channels
{
volatile uint32_t SC;
volatile uint32_t CV;
} FTM_CH_t;
typedef struct // FTM register block (this layout is compatible to a TPM register block)
{
volatile uint32_t SC;
volatile uint32_t CNT;
volatile uint32_t MOD;
FTM_CH_t CH[8];
volatile uint32_t CNTIN;
volatile uint32_t STATUS;
volatile uint32_t MODE;
volatile uint32_t SYNC;
volatile uint32_t OUTINIT;
volatile uint32_t OUTMASK;
volatile uint32_t COMBINE;
volatile uint32_t DEADTIME;
volatile uint32_t EXTTRIG;
volatile uint32_t POL;
volatile uint32_t FMS;
volatile uint32_t FILTER;
volatile uint32_t FLTCTRL;
volatile uint32_t QDCTRL;
volatile uint32_t CONF;
volatile uint32_t FLTPOL;
volatile uint32_t SYNCONF;
volatile uint32_t INVCTRL;
volatile uint32_t SWOCTRL;
volatile uint32_t PWMLOAD;
} FTM_r_t;
//=======================================================================
// using a static class instead of namespace here to reduce namespace pollution
// (anonymous namespace doesn't make sense for header only class)
template<unsigned module>
class FTM_Info
{
private:
#if defined(ARDUINO_TEENSYLC)
static constexpr unsigned boardNr = 0;
#elif defined(ARDUINO_TEENSY30)
static constexpr unsigned boardNr = 1;
#elif defined(ARDUINO_TEENSY31) || defined(ARDUINO_TEENSY32)
static constexpr unsigned boardNr = 2;
#elif defined(ARDUINO_TEENSY35)
static constexpr unsigned boardNr = 3;
#elif defined(ARDUINO_TEENSY36)
static constexpr unsigned boardNr = 4;
#else
#error Board not valid
#endif
static constexpr int IRQ_Numbers[][4]
{ //FTM0 FTM1 FTM2 FTM3
{ 0, 0, 0, 0 }, // Teensy LC
{ 25, 26, 0, 0 }, // Teensy 3.0
{ 62, 63, 64, 0 }, // Teensy 3.1/3.2
{ 42, 43, 44, 71 }, // Teensy 3.5
{ 42, 43, 44, 71 }, // Teensy 3.6
};
static constexpr int FTM_NrOfChannels[]
{
8, // FTM0
2, // FTM1
2, // FTM2
8, // FTM3
};
static constexpr uintptr_t FTM_BaseAdr[] // can't use defines from kinetis.h since, depending on board, not all are always defined.
{
0x4003'8000, // FTM0
0x4003'9000, // FTM1
0x400B'8000, // FTM2
0x400B'9000, // FTM3
};
static constexpr unsigned FTM_Prescale =
FTM_DEFAULT_PSC[module] < 0 || FTM_DEFAULT_PSC[module] > 7 ? // prescale value to roughly get 2 ticks per µs
(
F_BUS > 120'000'000 ? 0b111 :
F_BUS > 60'000'000 ? 0b110 :
F_BUS > 30'000'000 ? 0b101 :
F_BUS > 15'000'000 ? 0b100 :
F_BUS > 8'000'000 ? 0b011 :
F_BUS > 4'000'000 ? 0b010 :
F_BUS > 2'000'000 ? 0b001 : 0b000
):FTM_DEFAULT_PSC[module];
public:
static constexpr uintptr_t baseAdr = FTM_BaseAdr[module];
static constexpr IRQ_NUMBER_t irqNumber = (IRQ_NUMBER_t)IRQ_Numbers[boardNr][module];
static constexpr unsigned nrOfChannels = FTM_NrOfChannels[module];
static constexpr unsigned prescale = FTM_Prescale;
};
}

@ -0,0 +1,77 @@
#pragma once
#include "GPTChannel.h"
namespace TeensyTimerTool
{
template <unsigned moduleNr>
class GPT_t
{
public:
static ITimerChannel* getTimer();
protected:
static bool isInitialized;
static void isr();
static callback_t callback;
static GptChannel* channel;
// the following is calculated at compile time
static constexpr IRQ_NUMBER_t irq = moduleNr == 0 ? IRQ_GPT1 : IRQ_GPT2;
static IMXRT_GPT_t* const pGPT;
static_assert(moduleNr < 2, "Wrong GPT Number");
};
// IMPLEMENTATION ===========================================================================
template <unsigned moduleNr>
IMXRT_GPT_t* const GPT_t<moduleNr>::pGPT = reinterpret_cast<IMXRT_GPT_t*>(moduleNr == 0 ? &IMXRT_GPT1 : &IMXRT_GPT2);
template <unsigned moduleNr>
ITimerChannel* GPT_t<moduleNr>::getTimer()
{
if (!isInitialized)
{
isInitialized = true;
if (moduleNr == 0) // GPT1 clock settings
CCM_CCGR1 |= CCM_CCGR1_GPT1_BUS(CCM_CCGR_ON) | CCM_CCGR1_GPT1_SERIAL(CCM_CCGR_ON); //
else // GPT2
CCM_CCGR0 |= CCM_CCGR0_GPT2_BUS(CCM_CCGR_ON) | CCM_CCGR0_GPT2_SERIAL(CCM_CCGR_ON); //
//
if (USE_GPT_PIT_150MHz) // timer clock setting from config.h
CCM_CSCMR1 &= ~CCM_CSCMR1_PERCLK_CLK_SEL; // use F_BUS
else //
CCM_CSCMR1 |= CCM_CSCMR1_PERCLK_CLK_SEL; // use 24MHz
//
pGPT->CR = GPT_CR_CLKSRC(0x001) | GPT_CR_ENMOD; // stopped, restart mode and peripheral clock source
attachInterruptVector(irq, isr);
NVIC_ENABLE_IRQ(irq);
channel = new GptChannel(pGPT, &callback);
return channel;
}
return nullptr;
}
template <unsigned tmoduleNr>
void GPT_t<tmoduleNr>::isr()
{
if (!channel->periodic)
pGPT->CR &= ~GPT_CR_EN; // stop timer in one shot mode
//
pGPT->SR = 0x3F; // reset all interrupt flags
callback(); // we only enabled the OF1 interrupt-> no need to find out which interrupt was actually called
asm volatile("dsb"); // wait until register changes propagated through the cache
}
template <unsigned m>
bool GPT_t<m>::isInitialized = false;
template <unsigned m>
callback_t GPT_t<m>::callback = nullptr;
template <unsigned m>
GptChannel* GPT_t<m>::channel = nullptr;
}

@ -0,0 +1,116 @@
#pragma once
#include "../../ITimerChannel.h"
#include "GPTmap.h"
#include "core_pins.h"
namespace TeensyTimerTool
{
class GptChannel : public ITimerChannel
{
public:
inline GptChannel(IMXRT_GPT_t*, callback_t*);
inline virtual ~GptChannel();
inline errorCode begin(callback_t cb, float tcnt, bool periodic) override;
inline errorCode start() override;
inline errorCode stop() override;
inline errorCode trigger(float delay) override;
inline errorCode triggerDirect(uint32_t delay) override;
inline errorCode getTriggerReload(float delay, uint32_t* reload) override;
inline float getMaxPeriod() const override { return getMaxMicros() / 1E6; }
bool periodic;
protected:
inline uint32_t microsecondToCycles(float micros) const;
inline float getMaxMicros() const;
IMXRT_GPT_t* regs;
uint32_t reload;
float clock;
};
// IMPLEMENTATION ==============================================
GptChannel::GptChannel(IMXRT_GPT_t* registers, callback_t* cbStorage)
: ITimerChannel(cbStorage), regs(registers)
{
clock = (CCM_CSCMR1 & CCM_CSCMR1_PERCLK_CLK_SEL) ? 24 : (F_BUS_ACTUAL / 1000000);
}
errorCode GptChannel::begin(callback_t cb, float period, bool periodic)
{
this->periodic = periodic;
if (periodic)
{
reload = microsecondToCycles(period);
regs->OCR1 = reload;
}
setCallback(cb);
return errorCode::OK;
}
errorCode GptChannel::start()
{
regs->SR = 0x3F; // clear all interupt flags
regs->IR = GPT_IR_OF1IE; // enable OF1 interrupt
regs->CR |= GPT_CR_EN; // enable timer
return errorCode::OK;
}
errorCode GptChannel::stop()
{
regs->CR &= ~GPT_CR_EN; // disable timer
regs->IR = 0;
return errorCode::OK;
}
GptChannel::~GptChannel()
{
stop();
setCallback(nullptr);
}
errorCode GptChannel::trigger(float delay) //should be optimized somehow
{
return triggerDirect(microsecondToCycles(delay));
}
errorCode GptChannel::triggerDirect(uint32_t reload)
{
regs->SR = 0x3F; // clear all interupt flags
regs->IR = GPT_IR_OF1IE; // enable OF1 interrupt
regs->OCR1 = reload; // set overflow value
regs->CR |= GPT_CR_EN; // enable timer
return errorCode::OK;
}
errorCode GptChannel::getTriggerReload(float delay, uint32_t* reload)
{
*reload = microsecondToCycles(delay);
return errorCode::OK;
}
uint32_t GptChannel::microsecondToCycles(float micros) const
{
if (micros > getMaxMicros())
{
micros = getMaxPeriod();
postError(errorCode::periodOverflow);
}
return (uint32_t)(clock * micros) - 1;
}
float GptChannel::getMaxMicros() const
{
return (float)0xFFFF'FFFE / clock;
}
} // namespace TeensyTimerTool

@ -0,0 +1,32 @@
#pragma once
#include <cstdint>
#include <imxrt.h>
namespace TeensyTimerTool
{
struct IMXRT_GPT_t
{
//51.7.1 GPT Control Register
volatile uint32_t CR;
//51.7.2 GPT Prescaler Register(GPTx_PR)
volatile uint32_t PR;
//51.7.3 GPT Status Register(GPTx_SR)
volatile uint32_t SR;
//51.7.4 GPT Interrupt Register(GPTx_IR)
volatile uint32_t IR;
//51.7.5 GPT Output Compare Register (GPTx_OCR1)
volatile uint32_t OCR1;
//51.7.6 GPT Output Compare Register (GPTx_OCR2)
volatile uint32_t OCR2;
//51.7.7 GPT Output Compare Register (GPTx_OCR3)
volatile uint32_t OCR3;
//51.7.8 GPT Input Capture Register 1 (GPTx_ICR1)
volatile uint32_t ICR1;
//51.7.9 GPT Input Capture Register 1 (GPTx_ICR2)
volatile uint32_t ICR2;
//51.7.10 GPT Counter Register (GPTx_CNT)
volatile uint32_t CNT;
};
} // namespace TeensyTimerTool

@ -0,0 +1,13 @@
#if defined(ARDUINO_TEENSY40) || defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY_MICROMOD)
#include "PIT.h"
namespace TeensyTimerTool
{
bool PIT_t::isInitialized = false;
PITChannel PIT_t::channel[4] = {{0}, {1}, {2}, {3}};
uint32_t PITChannel::clockFactor = 1;
}
#endif

@ -0,0 +1,70 @@
#pragma once
#include "PITChannel.h"
namespace TeensyTimerTool
{
class PIT_t
{
public:
inline static ITimerChannel* getTimer();
protected:
static bool isInitialized;
static void isr();
static PITChannel channel[4];
};
// IMPLEMENTATION ===========================================================================
ITimerChannel* PIT_t::getTimer()
{
if (!isInitialized)
{
isInitialized = true;
CCM_CCGR1 |= CCM_CCGR1_PIT(CCM_CCGR_ON);
PIT_MCR = 1;
if (USE_GPT_PIT_150MHz) // timer clock setting from config.h
CCM_CSCMR1 &= ~CCM_CSCMR1_PERCLK_CLK_SEL; // FBus (usually 150MHz)
else
CCM_CSCMR1 |= CCM_CSCMR1_PERCLK_CLK_SEL; // 24MHz
attachInterruptVector(IRQ_PIT, isr);
NVIC_ENABLE_IRQ(IRQ_PIT);
}
for (unsigned i = 0; i < 4; i++)
{
if (channel[i].callback == nullptr) return &channel[i];
}
return nullptr;
}
inline void PIT_t::isr()
{
if (IMXRT_PIT_CHANNELS[0].TFLG)
{
IMXRT_PIT_CHANNELS[0].TFLG = 1;
channel[0].isr();
}
if (IMXRT_PIT_CHANNELS[1].TFLG)
{
IMXRT_PIT_CHANNELS[1].TFLG = 1;
channel[1].isr();
}
if (IMXRT_PIT_CHANNELS[2].TFLG)
{
IMXRT_PIT_CHANNELS[2].TFLG = 1;
channel[2].isr();
}
if (IMXRT_PIT_CHANNELS[3].TFLG)
{
IMXRT_PIT_CHANNELS[3].TFLG = 1;
channel[3].isr();
}
asm volatile("dsb"); //wait until register changes propagated through the cache
}
}

@ -0,0 +1,152 @@
#pragma once
#include "../../ITimerChannel.h"
#include "Arduino.h"
#include "PITMap.h"
namespace TeensyTimerTool
{
class PIT_t;
class PITChannel : public ITimerChannel
{
public:
inline PITChannel(unsigned nr);
inline virtual ~PITChannel();
inline errorCode begin(callback_t cb, float tcnt, bool periodic) override;
//inline errorCode begin(callback_t cb, uint32_t tcnt, bool periodic) override;
inline errorCode start() override;
inline errorCode stop() override;
//inline errorCode trigger(uint32_t) override;
inline errorCode trigger(float) override;
inline errorCode setNextPeriod(float us) override;
inline errorCode setPeriod(float us) override;
inline float getMaxPeriod() const override;
bool isPeriodic;
protected:
//IMXRT_GPT_t* regs;
//uint32_t reload;
inline void isr();
PITChannel() = delete;
PITChannel(const PITChannel&) = delete;
const unsigned chNr;
callback_t callback = nullptr;
static uint32_t clockFactor;
friend PIT_t;
};
// IMPLEMENTATION ==============================================
PITChannel::PITChannel(unsigned nr)
: ITimerChannel(nullptr), chNr(nr)
{
callback = nullptr;
clockFactor = (CCM_CSCMR1 & CCM_CSCMR1_PERCLK_CLK_SEL) ? 24 : (F_BUS_ACTUAL / 1000000);
}
errorCode PITChannel::begin(callback_t cb, float micros, bool periodic)
{
isPeriodic = periodic;
callback = cb;
if (isPeriodic)
{
IMXRT_PIT_CHANNELS[chNr].TCTRL = 0;
IMXRT_PIT_CHANNELS[chNr].TFLG = 1;
setNextPeriod(micros);
// float tmp = micros * clockFactor;
// if (tmp > 0xFFFF'FFFF)
// {
// postError(errorCode::periodOverflow);
// IMXRT_PIT_CHANNELS[chNr].LDVAL = 0xFFFF'FFFE;
// } else
// {
// IMXRT_PIT_CHANNELS[chNr].LDVAL = (uint32_t)tmp - 1;
// }
}
return errorCode::OK;
}
errorCode PITChannel::start()
{
IMXRT_PIT_CHANNELS[chNr].TCTRL = PIT_TCTRL_TEN | PIT_TCTRL_TIE;
return errorCode::OK;
}
errorCode PITChannel::stop()
{
IMXRT_PIT_CHANNELS[chNr].TCTRL = 0;
return errorCode::OK;
}
errorCode PITChannel::setNextPeriod(float us)
{
float cts = us * clockFactor;
if (cts > 0xFFFF'FFFF)
{
postError(errorCode::periodOverflow);
IMXRT_PIT_CHANNELS[chNr].LDVAL = 0xFFFF'FFFE;
} else
{
IMXRT_PIT_CHANNELS[chNr].LDVAL = (uint32_t)cts - 1;
}
return errorCode::OK;
}
errorCode PITChannel::setPeriod(float us)
{
stop(); // need to stop/start timer to change current period (see ch 53.9.5.4)
setNextPeriod(us);
start();
return errorCode::OK;
}
void PITChannel::isr()
{
if (callback != nullptr)
{
callback();
if (!isPeriodic) IMXRT_PIT_CHANNELS[chNr].TCTRL = 0; // switch off timer
}
}
PITChannel::~PITChannel()
{
callback = nullptr;
}
errorCode PITChannel::trigger(float delay) //should be optimized somehow
{
IMXRT_PIT_CHANNELS[chNr].TCTRL = 0;
IMXRT_PIT_CHANNELS[chNr].TFLG = 1;
float tmp = delay * clockFactor;
if (tmp > 0xFFFF'FFFF)
{
postError(errorCode::periodOverflow);
IMXRT_PIT_CHANNELS[chNr].LDVAL = 0xFFFF'FFFE;
} else
IMXRT_PIT_CHANNELS[chNr].LDVAL = (uint32_t)tmp - 1;
start();
return errorCode::OK;
}
float PITChannel::getMaxPeriod() const
{
return (float)0xFFFF'FFFE / clockFactor / 1'000'000;
}
} // namespace TeensyTimerTool

@ -0,0 +1,32 @@
#pragma once
#include <cstdint>
#include <imxrt.h>
namespace TeensyTimerTool
{
// struct IMXRT_GPT_t
// {
// //51.7.1 GPT Control Register
// volatile uint32_t CR;
// //51.7.2 GPT Prescaler Register(GPTx_PR)
// volatile uint32_t PR;
// //51.7.3 GPT Status Register(GPTx_SR)
// volatile uint32_t SR;
// //51.7.4 GPT Interrupt Register(GPTx_IR)
// volatile uint32_t IR;
// //51.7.5 GPT Output Compare Register (GPTx_OCR1)
// volatile uint32_t OCR1;
// //51.7.6 GPT Output Compare Register (GPTx_OCR2)
// volatile uint32_t OCR2;
// //51.7.7 GPT Output Compare Register (GPTx_OCR3)
// volatile uint32_t OCR3;
// //51.7.8 GPT Input Capture Register 1 (GPTx_ICR1)
// volatile uint32_t ICR1;
// //51.7.9 GPT Input Capture Register 1 (GPTx_ICR2)
// volatile uint32_t ICR2;
// //51.7.10 GPT Counter Register (GPTx_CNT)
// volatile uint32_t CNT;
// };
} // namespace TeensyTimerTool

@ -0,0 +1,41 @@
#include "../../config.h"
#if defined(TEENSYDUINO)
#include "TCK.h"
namespace TeensyTimerTool
{
bool TCK_t::isInitialized = false;
TckChannelBase* TCK_t::channels[NR_OF_TCK_TIMERS];
}
//----------------------------------------------------------------------
#if YIELD_TYPE == YIELD_OPTIMIZED
void yield()
{
TeensyTimerTool::TCK_t::tick();
}
//----------------------------------------------------------------------
#elif YIELD_TYPE == YIELD_STANDARD
#include "EventResponder.h"
namespace TeensyTimerTool
{
static EventResponder er;
void initYieldHook()
{
er.attach([](EventResponderRef r)
{
TeensyTimerTool::TCK_t::tick();
r.triggerEvent();
});
er.triggerEvent();
}
}
#endif
#endif
//#endif

@ -0,0 +1,82 @@
#pragma once
//#include "TckChannelBase.h"
#include "TckChannel.h"
#include "core_pins.h"
namespace TeensyTimerTool
{
extern const unsigned NR_OF_TCK_TIMERS;
class TCK_t
{
public:
template<typename counterType> static inline ITimerChannel* getTimer();
static inline void removeTimer(TckChannelBase*);
static inline void tick();
protected:
static bool isInitialized;
static TckChannelBase* channels[NR_OF_TCK_TIMERS];
};
// IMPLEMENTATION ==================================================================
template<typename counterType>
ITimerChannel* TCK_t::getTimer()
{
if (!isInitialized)
{
for (unsigned chNr = 0; chNr < NR_OF_TCK_TIMERS; chNr++)
{
channels[chNr] = nullptr;
}
isInitialized = true;
// enable the cycle counter
ARM_DEMCR |= ARM_DEMCR_TRCENA;
ARM_DWT_CTRL |= ARM_DWT_CTRL_CYCCNTENA;
// initialize the yield hook
#if defined(TEENSYDUINO) && YIELD_TYPE == YIELD_STANDARD
extern void initYieldHook();
initYieldHook();
#endif
}
for (unsigned chNr = 0; chNr < NR_OF_TCK_TIMERS; chNr++)
{
if (channels[chNr] == nullptr)
{
channels[chNr] = new TckChannel<counterType>();
return channels[chNr];
}
}
return nullptr;
}
void TCK_t::removeTimer(TckChannelBase* channel)
{
for (unsigned chNr = 0; chNr < NR_OF_TCK_TIMERS; chNr++)
{
if (channels[chNr] == channel)
{
channels[chNr] = nullptr;
delete channel;
break;
}
}
}
void TCK_t::tick()
{
for (unsigned i = 0; i < NR_OF_TCK_TIMERS; i++)
{
if (channels[i] != nullptr)
{
channels[i]->tick();
}
}
}
}

@ -0,0 +1,336 @@
#pragma once
//#include "Arduino.h"
#include "ErrorHandling/error_codes.h"
#include "TckChannelBase.h"
#include "core_pins.h"
namespace TeensyTimerTool
{
class TCK_t;
#if !defined(ARDUINO_TEENSYLC) // T-LC doesn't have a cycle counter, nees special treatment
template <typename CounterType>
class TckChannel : public TckChannelBase
{
public:
TckChannel();
virtual ~TckChannel(){}; //TBD
inline errorCode begin(callback_t cb, float period, bool periodic) override;
inline errorCode start() override;
inline errorCode stop() override;
inline errorCode trigger(float delay_us) override;
inline errorCode triggerDirect(CounterType reload) override;
inline errorCode getTriggerReload(float delay, CounterType* reload) override
{
*reload = microsecondToCycles(delay);
return errorCode::OK;
}
float getMaxPeriod() const override { return getMaxMicros() / 1E6; } // seconds
CounterType getCycleCounter() { postError(errorCode::wrongType); }
// inline errorCode setPeriod(uint32_t microSeconds) override;
// inline errorCode setPeriod(uint32_t microSeconds) override;
// inline errorCode setNextPeriod(uint32_t microSeconds) override;
protected:
inline CounterType microsecondToCycles(const float microSecond) const;
float getMaxMicros() const;
inline bool tick();
callback_t callback;
bool periodic;
bool triggered;
// bool block = false;
CounterType startCnt, currentPeriod, nextPeriod;
uint32_t lastCyCnt;
uint32_t curHIGH;
float clock;
friend TCK_t;
// inline uint32_t CPUCyclesToMicroseond(const uint32_t cpuCycles);
// inline errorCode _setCurrentPeriod(const uint32_t period);
// inline void _setNextPeriod(const uint32_t period);
};
// IMPLEMENTATION ==============================================
template <typename T>
TckChannel<T>::TckChannel()
{
triggered = false;
clock = F_CPU / 1'000'000.0f;
}
template <typename T>
errorCode TckChannel<T>::begin(callback_t cb, float period, bool periodic)
{
this->triggered = false;
this->periodic = periodic;
if (periodic)
{
this->currentPeriod = microsecondToCycles(period);
this->nextPeriod = this->currentPeriod;
}
this->callback = cb;
return errorCode::OK;
}
template <typename T>
errorCode TckChannel<T>::start()
{
this->startCnt = getCycleCounter();
this->triggered = true;
return errorCode::OK;
}
template <typename T>
errorCode TckChannel<T>::stop()
{
this->triggered = false;
return errorCode::OK;
}
template <typename CounterType>
errorCode TckChannel<CounterType>::triggerDirect(CounterType reload)
{
this->startCnt = getCycleCounter();
this->nextPeriod = reload;
this->currentPeriod = this->nextPeriod;
this->triggered = true;
return errorCode::OK;
}
template <typename T>
errorCode TckChannel<T>::trigger(float delay) // µs
{
return triggerDirect(microsecondToCycles(delay));
}
template <typename counter_t>
bool TckChannel<counter_t>::tick()
{
static bool lock = false;
counter_t now = getCycleCounter();
if (!lock && this->currentPeriod != 0 && this->triggered && (now - this->startCnt) >= this->currentPeriod)
{
lock = true;
//this->startCnt = now;
this->startCnt += currentPeriod;
this->triggered = this->periodic; // i.e., stays triggerd if periodic, stops if oneShot
callback();
lock = false;
return true;
} else
{
return false;
}
}
template <typename CounterType>
CounterType TckChannel<CounterType>::microsecondToCycles(float microSecond) const
{
if (microSecond > getMaxMicros())
{
microSecond = getMaxMicros();
postError(errorCode::periodOverflow);
}
return (CounterType)(microSecond * clock);
}
// SPECIALIZATIONS =================================================================================
// 32bit Counter -------------------------------------------------------------------------
template <>
inline uint32_t TckChannel<uint32_t>::getCycleCounter()
{
return ARM_DWT_CYCCNT; //directly use the cycle counter for uint32_t
}
template <>
inline float TckChannel<uint32_t>::getMaxMicros() const
{
return 0xF000'0000 / clock; // don't use full range otherwise tick might miss the turnover for large periods
}
// 64bit Counter -------------------------------------------------------------------------
template <>
inline uint64_t TckChannel<uint64_t>::getCycleCounter()
{
uint32_t now = ARM_DWT_CYCCNT; // (extend the cycle counter to 64 bit)
if (now < lastCyCnt)
{
curHIGH++;
}
lastCyCnt = now;
return (((uint64_t)curHIGH << 32) | now);
}
template <>
inline float TckChannel<uint64_t>::getMaxMicros() const
{
return 0xFFFF'FFFF; // currently limited to 2^32 µs (71.6h). Could be extended to 2^64 but would require change of interface
}
// template <typename ct>
// uint32_t TckChannel<ct>::CPUCyclesToMicroseond(const uint32_t cpuCycles)
// {
// return (1'000'000.0f / F_CPU) * cpuCycles;
// }
// template <typename ct>
// void TckChannel<ct>::_setNextPeriod(const uint32_t period)
// {
// this->nextPeriod = period;
// }
// template <typename ct>
// errorCode TckChannel<ct>::_setCurrentPeriod(const uint32_t period)
// {
// this->currentPeriod = period;
// const bool hasTicked = this->tick();
// if (hasTicked)
// {
// return errorCode::triggeredLate;
// } else
// {
// return errorCode::OK;
// }
// }
// template <typename ct>
// errorCode TckChannel<ct>::setPeriod(uint32_t microSeconds)
// {
// const uint32_t period = microsecondToCPUCycles(microSeconds);
// this->_setNextPeriod(period);
// return this->_setCurrentPeriod(period);
// }
// template <typename ct>
// errorCode TckChannel<ct>::setPeriod(uint32_t microSeconds)
// {
// const uint32_t period = microsecondToCPUCycles(microSeconds);
// return this->_setCurrentPeriod(period);
// }
// template <typename ct>
// errorCode TckChannel<ct>::setNextPeriod(uint32_t microSeconds)
// {
// const uint32_t period = microsecondToCPUCycles(microSeconds);
// this->_setNextPeriod(period);
// return errorCode::OK;
// }
#else // TeensyLC
// Quick hack only, needs to be improved
template <typename uint32_64_t>
class TckChannel : public TckChannelBase
{
public:
TckChannel() { triggered = false; }
virtual ~TckChannel(){};
errorCode begin(callback_t cb, float period, bool periodic) override
{
triggered = false;
this->periodic = periodic;
this->period = (uint32_t)period;
this->callback = cb;
return errorCode::OK;
}
errorCode start()
{
this->startCNT = micros();
this->triggered = true;
return errorCode::OK;
}
errorCode stop()
{
this->triggered = false;
return errorCode::OK;
}
inline errorCode setPeriod(uint32_t microSeconds) override;
inline uint32_t getPeriod(void);
inline errorCode trigger(float delay) // µs
{
this->startCNT = micros();
this->period = (uint32_t)delay;
this->triggered = true;
return errorCode::OK;
}
float getMaxPeriod() const override { return getMaxMicros() / 1E6; } // seconds
protected:
static constexpr float clock = F_CPU / 1'000'000.0f;
float getMaxMicros() const { return 0xF000'0000 / clock; } // don't use full range otherwise tick might miss the turnover for large periods
uint32_t startCNT, period;
callback_t callback;
bool triggered;
bool periodic;
inline bool tick();
bool block = false;
friend TCK_t;
};
// IMPLEMENTATION ==============================================
template <typename ct>
bool TckChannel<ct>::tick()
{
static bool lock = false;
if (!lock && period != 0 && triggered && (micros() - startCNT) >= period)
{
lock = true;
startCNT = micros();
triggered = periodic; // i.e., stays triggerd if periodic, stops if oneShot
callback();
lock = false;
return true;
}
return false;
}
template <typename ct>
errorCode TckChannel<ct>::setPeriod(uint32_t microSeconds)
{
period = microSeconds;
return errorCode::OK;
}
template <typename ct>
uint32_t TckChannel<ct>::getPeriod()
{
return period;
}
#endif
} // namespace TeensyTimerTool

@ -0,0 +1,15 @@
#pragma once
#include "../../ITimerChannel.h"
namespace TeensyTimerTool
{
class TckChannelBase : public ITimerChannel
{
public:
virtual bool tick() = 0;
virtual ~TckChannelBase() = 0;
};
inline TckChannelBase::~TckChannelBase() {}
}

@ -0,0 +1,100 @@
#pragma once
#include "TMRChannel.h"
#include "imxrt.h"
namespace TeensyTimerTool
{
template <unsigned moduleNr>
class TMR_t
{
public:
static ITimerChannel* getTimer();
protected:
static bool isInitialized;
static void isr();
static callback_t callbacks[4];
// the following is calculated at compile time
static constexpr IRQ_NUMBER_t irq = moduleNr == 0 ? IRQ_QTIMER1 : moduleNr == 1 ? IRQ_QTIMER2 : moduleNr == 2 ? IRQ_QTIMER3 : IRQ_QTIMER4;
static IMXRT_TMR_t* const pTMR;
static IMXRT_TMR_CH_t* const pCH0;
static IMXRT_TMR_CH_t* const pCH1;
static IMXRT_TMR_CH_t* const pCH2;
static IMXRT_TMR_CH_t* const pCH3;
static_assert(moduleNr < 4, "Module number < 4 required");
};
// IMPLEMENTATION ==================================================================
template <unsigned moduleNr> IMXRT_TMR_t* const TMR_t<moduleNr>::pTMR = moduleNr == 0 ? &IMXRT_TMR1 : moduleNr == 1 ? &IMXRT_TMR2 : moduleNr == 2 ? &IMXRT_TMR3 : &IMXRT_TMR4;
template <unsigned moduleNr> IMXRT_TMR_CH_t* const TMR_t<moduleNr>::pCH0 = &pTMR->CH[0];
template <unsigned moduleNr> IMXRT_TMR_CH_t* const TMR_t<moduleNr>::pCH1 = &pTMR->CH[1];
template <unsigned moduleNr> IMXRT_TMR_CH_t* const TMR_t<moduleNr>::pCH2 = &pTMR->CH[2];
template <unsigned moduleNr> IMXRT_TMR_CH_t* const TMR_t<moduleNr>::pCH3 = &pTMR->CH[3];
template <unsigned moduleNr>
ITimerChannel* TMR_t<moduleNr>::getTimer()
{
if (!isInitialized)
{
for (unsigned chNr = 0; chNr < 4; chNr++)
{
pTMR->CH[chNr].CTRL = 0x0000;
callbacks[chNr] = nullptr;
}
attachInterruptVector(irq, isr); // start
NVIC_ENABLE_IRQ(irq);
isInitialized = true;
return new TMRChannel(pCH0, &callbacks[0]);
}
for (unsigned chNr = 0; chNr < 4; chNr++)
{
IMXRT_TMR_CH_t* pCh = &pTMR->CH[chNr];
if (pCh->CTRL == 0x0000)
{
return new TMRChannel(pCh, &callbacks[chNr]);
}
}
return nullptr;
}
template <unsigned m>
void TMR_t<m>::isr()
{
// no loop to gain some time by avoiding indirections and pointer calculations
if (callbacks[0] != nullptr && pCH0->CSCTRL & TMR_CSCTRL_TCF1)
{
pCH0->CSCTRL &= ~TMR_CSCTRL_TCF1;
callbacks[0]();
}
if (callbacks[1] != nullptr && pCH1->CSCTRL & TMR_CSCTRL_TCF1)
{
pCH1->CSCTRL &= ~TMR_CSCTRL_TCF1;
callbacks[1]();
}
if (callbacks[2] != nullptr && pCH2->CSCTRL & TMR_CSCTRL_TCF1)
{
pCH2->CSCTRL &= ~TMR_CSCTRL_TCF1;
callbacks[2]();
}
if (callbacks[3] != nullptr && pCH3->CSCTRL & TMR_CSCTRL_TCF1)
{
pCH3->CSCTRL &= ~TMR_CSCTRL_TCF1;
callbacks[3]();
}
asm volatile("dsb"); //wait until register changes propagated through the cache
}
template <unsigned m>
bool TMR_t<m>::isInitialized = false;
template <unsigned m>
callback_t TMR_t<m>::callbacks[4];
}

@ -0,0 +1,178 @@
#pragma once
#include "../../ITimerChannel.h"
//#include "Arduino.h"
#include <cmath>
#include "ErrorHandling/error_codes.h"
#include "config.h"
#include "imxrt.h"
namespace TeensyTimerTool
{
class TMRChannel : public ITimerChannel
{
public:
inline TMRChannel(IMXRT_TMR_CH_t* regs, callback_t* cbStorage);
inline virtual ~TMRChannel();
inline errorCode begin(callback_t cb, float tcnt, bool periodic) override;
inline errorCode start() override;
inline errorCode stop() override;
inline errorCode trigger(float tcnt) override;
inline float getMaxPeriod() const override;
inline errorCode setPeriod(float us) override;
inline void setPrescaler(uint32_t psc); // psc 0..7 -> prescaler: 1..128
protected:
IMXRT_TMR_CH_t* regs;
callback_t** pCallback = nullptr;
float pscValue;
uint32_t pscBits;
inline float_t microsecondToCounter(const float_t us) const;
inline float_t counterToMicrosecond(const float_t cnt) const;
};
// IMPLEMENTATION ==============================================
TMRChannel::TMRChannel(IMXRT_TMR_CH_t* regs, callback_t* cbStorage)
: ITimerChannel(cbStorage)
{
this->regs = regs;
setPrescaler(TMR_DEFAULT_PSC);
}
TMRChannel::~TMRChannel()
{
}
errorCode TMRChannel::start()
{
regs->CNTR = 0x0000;
regs->CSCTRL &= ~TMR_CSCTRL_TCF1;
regs->CSCTRL |= TMR_CSCTRL_TCF1EN;
return errorCode::OK;
}
errorCode TMRChannel::stop()
{
regs->CSCTRL &= ~TMR_CSCTRL_TCF1EN;
return errorCode::OK;
}
errorCode TMRChannel::begin(callback_t cb, float tcnt, bool periodic)
{
const float_t t = microsecondToCounter(tcnt);
uint16_t reload;
if (t > 0xFFFF)
{
postError(errorCode::periodOverflow);
reload = 0xFFFE;
} else
{
reload = (uint16_t)t - 1;
}
regs->CTRL = 0x0000;
regs->LOAD = 0x0000;
regs->COMP1 = reload;
regs->CMPLD1 = reload;
regs->CNTR = 0x0000;
setCallback(cb);
if (!periodic)
regs->CTRL = TMR_CTRL_CM(1) | TMR_CTRL_PCS(pscBits) | TMR_CTRL_ONCE | TMR_CTRL_LENGTH;
else
regs->CTRL = TMR_CTRL_CM(1) | TMR_CTRL_PCS(pscBits) | TMR_CTRL_LENGTH;
start();
return t > 0xFFFF ? errorCode::periodOverflow : errorCode::OK;
}
errorCode TMRChannel::trigger(float tcnt) // quick and dirty, should be optimized
{
const float_t t = microsecondToCounter(tcnt);
uint16_t reload = t > 0xFFFF ? 0xFFFF : (uint16_t)t;
regs->CTRL = 0x0000;
regs->LOAD = 0x0000;
regs->COMP1 = reload;
regs->CMPLD1 = reload;
regs->CNTR = 0x0000;
regs->CSCTRL &= ~TMR_CSCTRL_TCF1;
regs->CSCTRL |= TMR_CSCTRL_TCF1EN;
regs->CTRL = TMR_CTRL_CM(1) | TMR_CTRL_PCS(pscBits) | TMR_CTRL_ONCE | TMR_CTRL_LENGTH;
return errorCode::OK;
}
void TMRChannel::setPrescaler(uint32_t psc) // psc 0..7 -> prescaler: 1..128
{
pscValue = 1 << (psc & 0b0111);
pscBits = 0b1000 | (psc & 0b0111);
}
float TMRChannel::getMaxPeriod() const
{
return pscValue / 150'000'000.0f * 0xFFFE;
}
// void TMRChannel::_setNextPeriod(const uint16_t cnt)
// {
// regs->CMPLD1 = cnt;
// }
// errorCode TMRChannel::_setCurrentPeriod(const uint16_t cnt)
// {
// regs->COMP1 = cnt;
// //Do we need to wait some cycle for IP bus to update here / cache flush?
// //asm volatile("dsb");
// if (regs->CNTR > cnt)
// {
// //if counter alrready went over setted value force a triggering
// regs->CNTR = cnt;
// return errorCode::triggeredLate;
// }
// else
// {
// return errorCode::OK;
// }
// }
errorCode TMRChannel::setPeriod(float us)
{
//const float_t t = microsecondToCounter(us);
// if (t <= 0xFFFF)
// {
// return _setCurrentPeriod(t);
// } else
// {
// return errorCode::periodOverflow;
// }
return errorCode::notImplemented;
}
float_t TMRChannel::microsecondToCounter(const float_t us) const
{
return us * 150.0f / pscValue;
}
float_t TMRChannel::counterToMicrosecond(const float_t cnt) const
{
return cnt * pscValue / 150.0f;
}
} // namespace TeensyTimerTool

@ -0,0 +1,9 @@
#pragma once
#include "config.h"
#include "timer.h"
#include "periodicTimer.h"
#include "oneShotTimer.h"
#include "ErrorHandling/error_handler.h"
static_assert(TEENSYDUINO >= 150, "This library requires Teensyduino > 1.5");

@ -0,0 +1,10 @@
#include "timer.h"
#include "config.h"
namespace TeensyTimerTool
{
Timer::Timer(TimerGenerator* generator)
:BaseTimer(generator, true)
{
}
}

@ -0,0 +1,14 @@
//#include "../../TeensyTimerTool.h"
#include "../../config.h"
#if defined(HAS_TCK) and defined(UNO)
namespace TeensyTimerTool
{
bool TCK_t::isInitialized = false;
TckChannel* TCK_t::channels[maxTckChannels];
}
void yield() { TeensyTimerTool::TCK_t::tick(); }
#endif

@ -0,0 +1,79 @@
#pragma once
#include "TckChannel.h"
#include <Arduino.h>
#include <cstdint>
namespace TeensyTimerTool
{
constexpr unsigned maxTckChannels = 20;
class TCK_t
{
public:
static inline ITimerChannel* getTimer();
static inline void removeTimer(TckChannel*);
static inline void tick();
protected:
static bool isInitialized;
static TckChannel* channels[maxTckChannels];
};
// IMPLEMENTATION ==================================================================
ITimerChannel* TCK_t::getTimer()
{
Serial.printf("TCK getTimer()\n");
if (!isInitialized)
{
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
channels[chNr] = nullptr;
}
isInitialized = true;
}
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
if (channels[chNr] == nullptr)
{
channels[chNr] = new TckChannel();
return channels[chNr];
}
}
return nullptr;
}
void TCK_t::removeTimer(TckChannel* channel)
{
for (unsigned chNr = 0; chNr < maxTckChannels; chNr++)
{
if (channels[chNr] == channel)
{
channels[chNr] = nullptr;
delete channel;
break;
}
}
}
void TCK_t::tick()
{
digitalWriteFast(12,HIGH);
for(unsigned i = 0; i < maxTckChannels; i++)
{
if (channels[i] != nullptr )
{
channels[i]->tick();
}
}
digitalWriteFast(12,LOW);
}
//constexpr TimerGenerator* TCK = TCK_t::getTimer;
} // namespace TeensyTimerTool

@ -0,0 +1,89 @@
#pragma once
#include "../ITimerChannel.h"
#include "../types.h"
#include "Arduino.h"
namespace TeensyTimerTool
{
class TCK_t;
class TckChannel : public ITimerChannel
{
public:
inline TckChannel() { triggered = false; }
inline virtual ~TckChannel(){};
inline void begin(callback_t cb, unsigned period, bool periodic)
{
Serial.println("begin");
triggered = false;
this->periodic = periodic;
this->period = period * (F_CPU / 1'000'000);
this->callback = cb;
startCNT = ARM_DWT_CYCCNT;
}
inline void start()
{
Serial.println("start");
this->startCNT = ARM_DWT_CYCCNT;
this->triggered = true;
}
inline void stop()
{
this->triggered = false;
}
// inline void setPeriod(uint32_t microSeconds);
inline uint32_t getPeriod(void);
inline void trigger(uint32_t delay) // µs
{
this->startCNT = ARM_DWT_CYCCNT;
this->period = delay * (F_CPU / 1'000'000) - 68;
this->triggered = true;
}
protected:
uint32_t startCNT, period;
callback_t callback;
bool triggered;
bool periodic;
inline void tick();
bool block = false;
friend TCK_t;
};
// IMPLEMENTATION ==============================================
void TckChannel::tick()
{
static bool lock = false;
if (!lock && period != 0 && triggered && (ARM_DWT_CYCCNT - startCNT) >= period)
{
lock = true;
startCNT = ARM_DWT_CYCCNT;
triggered = periodic; // i.e., stays triggerd if periodic, stops if oneShot
callback();
lock = false;
}
}
// void TckChannel::setPeriod(uint32_t microSeconds)
// {
// period = microSeconds * (F_CPU / 1'000'000) ;
// }
uint32_t TckChannel::getPeriod()
{
return period * (1'000'000.0f / F_CPU);
}
} // namespace TeensyTimerTool

@ -0,0 +1,22 @@
#include "baseTimer.h"
#include "Arduino.h"
#include "types.h"
namespace TeensyTimerTool
{
BaseTimer::BaseTimer(TimerGenerator* generator, bool periodic)
: timerGenerator(generator)
{
this->timerGenerator = generator;
this->timerChannel = nullptr;
this->isPeriodic = periodic;
}
errorCode BaseTimer::setPrescaler(int psc)
{
this->prescaler = psc;
return errorCode::OK;
}
}

@ -0,0 +1,116 @@
#pragma once
//#include "Arduino.h"
#include "ErrorHandling/error_codes.h"
#include "ITimerChannel.h"
#include <type_traits>
#if defined(USE_TIME_LITERALS)
# include "frequency.h"
# include <chrono>
using namespace std::chrono_literals;
using namespace std::chrono;
#endif
namespace TeensyTimerTool
{
class BaseTimer
{
public:
template <typename T>
inline errorCode begin(callback_t callback, T period, bool start = true);
inline errorCode setPrescaler(int psc);
inline errorCode end();
inline errorCode start();
inline errorCode stop();
inline float getMaxPeriod() const;
protected:
template <class T, std::enable_if_t<std::is_arithmetic<T>::value, int>* = nullptr>
T getPeriod(T v) { return v; }
BaseTimer(TimerGenerator* generator, bool periodic);
TimerGenerator* timerGenerator;
ITimerChannel* timerChannel;
bool isPeriodic;
uint32_t prescaler = 0;
#if defined(USE_TIME_LITERALS)
public:
template <typename dur = seconds>
inline float getMaxDuration() const { return getMaxPeriod() * dur::period::den / dur::period::num; }
protected:
template <class T, std::enable_if_t<std::chrono::__is_duration<T>::value, int>* = nullptr>
float getPeriod(T v) { return (duration_cast<duration<float, std::micro>>(v).count()); }
template <class T, std::enable_if_t<TeensyTimerTool::__is_frequency<T>::value, int>* = nullptr>
float getPeriod(T v) { return 1'000'000 / duration_cast<hertz>(v).count(); }
#endif
};
// INLINE IMPLEMENTATION ================================================
template <typename T>
errorCode BaseTimer::begin(callback_t callback, T p, bool start)
{
auto period = getPeriod(p);
if (callback == nullptr) return postError(errorCode::callback);
if (isPeriodic && period == 0) return postError(errorCode::reload);
if (timerChannel == nullptr)
{
if (timerGenerator != nullptr) // use timer passed in during construction
{
timerChannel = timerGenerator();
if (timerChannel == nullptr) return postError(errorCode::noFreeChannel);
} else //find the next free timer
{
for (unsigned i = 0; timerChannel == nullptr && i < timerCnt; i++)
{
timerChannel = timerPool[i]();
}
}
if (timerChannel == nullptr) return postError(errorCode::noFreeModule);
}
errorCode result = timerChannel->begin(callback, period, isPeriodic);
if (result == errorCode::OK)
{
if (isPeriodic && start) timerChannel->start();
}
return postError(result);
}
errorCode BaseTimer::end()
{
return postError(errorCode::notImplemented);
}
errorCode BaseTimer::start()
{
timerChannel->start();
return errorCode::OK; // hack, implement return value in timer interface
}
errorCode BaseTimer::stop()
{
return postError(timerChannel->stop());
}
float BaseTimer::getMaxPeriod() const
{
if (timerChannel != nullptr)
{
return timerChannel->getMaxPeriod();
}
postError(errorCode::notInitialized);
return 0;
}
}

@ -0,0 +1,66 @@
#pragma once
#include <cstdint>
namespace TeensyTimerTool
{
class ITimerChannel;
using TimerGenerator = ITimerChannel*(); //returns a pointer to a free timer channel or nullptr
// TEENSYDUINO ==========================================================================
#if defined(TEENSYDUINO)
#if defined(ARDUINO_TEENSYLC)
extern TimerGenerator *const TCK;
#elif defined(ARDUINO_TEENSY30)
extern TimerGenerator *const FTM0, * const FTM1;
extern TimerGenerator *const TCK, * const TCK32, * const TCK64;
#elif defined(ARDUINO_TEENSY31) || defined(ARDUINO_TEENSY32)
extern TimerGenerator *const FTM0, * const FTM1, * const FTM2;
extern TimerGenerator *const TCK, * const TCK32, * const TCK64;
#elif defined(ARDUINO_TEENSY35)
extern TimerGenerator *const FTM0, * const FTM1, * const FTM2, * const FTM3, * const FTM4;
extern TimerGenerator *const TCK, * const TCK32, * const TCK64;
#elif defined(ARDUINO_TEENSY36)
extern TimerGenerator *const FTM0, *const FTM1, *const FTM2, *const FTM3, *const FTM4;
extern TimerGenerator *const TCK, * const TCK32, * const TCK64;
#elif defined(ARDUINO_TEENSY40) || defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY_MICROMOD)
extern TimerGenerator *const TMR1, *const TMR2, *const TMR3, *const TMR4;
extern TimerGenerator *const GPT1, *const GPT2;
extern TimerGenerator *const PIT;
extern TimerGenerator *const TCK, * const TCK32, * const TCK64;
#else
#error BOARD NOT SUPPORTED
#endif
#define YIELD_NONE 0
#define YIELD_STANDARD 1
#define YIELD_OPTIMIZED 2
constexpr int PSC_AUTO = -1;
constexpr int PSC_1 = 0;
constexpr int PSC_2 = 1;
constexpr int PSC_4 = 2;
constexpr int PSC_8 = 3;
constexpr int PSC_16 = 4;
constexpr int PSC_32 = 5;
constexpr int PSC_64 = 6;
constexpr int PSC_128 = 7;
extern void(* const tick)();
// ESP32 ==========================================================================
#elif defined(ESP32)
//...
#else
# error "Board not supported"
#endif
}

@ -0,0 +1,88 @@
#include "config.h"
#include "boardDef.h"
using tick_t = void (*) ();
#if defined(ARDUINO_TEENSY40) || defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY_MICROMOD)
#include "Teensy/TMR/TMR.h"
#include "Teensy/GPT/GPT.h"
#include "Teensy/PIT4/PIT.h"
#include "Teensy/TCK/TCK.h"
namespace TeensyTimerTool
{
TimerGenerator* const TMR1 = TMR_t<0>::getTimer;
TimerGenerator* const TMR2 = TMR_t<1>::getTimer;
TimerGenerator* const TMR3 = TMR_t<2>::getTimer;
TimerGenerator* const TMR4 = TMR_t<3>::getTimer;
TimerGenerator* const GPT1 = GPT_t<0>::getTimer;
TimerGenerator* const GPT2 = GPT_t<1>::getTimer;
TimerGenerator* const PIT = PIT_t::getTimer;
TimerGenerator* const TCK = TCK_t::getTimer<uint32_t>;
TimerGenerator* const TCK32 = TCK_t::getTimer<uint32_t>; // same as TCK
TimerGenerator* const TCK64 = TCK_t::getTimer<uint64_t>;
constexpr tick_t tick = &TCK_t::tick;
}
#elif defined (ARDUINO_TEENSY35) || defined (ARDUINO_TEENSY36)
#include "Teensy/FTM/FTM.h"
#include "Teensy/TCK/TCK.h"
namespace TeensyTimerTool
{
TimerGenerator* const TCK = TCK_t::getTimer<uint32_t>;
TimerGenerator* const TCK32 = TCK_t::getTimer<uint32_t>; // same as TCK
TimerGenerator* const TCK64 = TCK_t::getTimer<uint64_t>;
TimerGenerator* const FTM0 = FTM_t<0>::getTimer;
TimerGenerator* const FTM1 = FTM_t<1>::getTimer;
TimerGenerator* const FTM2 = FTM_t<2>::getTimer;
TimerGenerator* const FTM3 = FTM_t<3>::getTimer;
TimerGenerator* const FTM4 = FTM_t<3>::getTimer;
constexpr tick_t tick = &TCK_t::tick;
}
#elif defined(ARDUINO_TEENSY31) || defined (ARDUINO_TEENSY32)
#include "Teensy/FTM/FTM.h"
#include "Teensy/TCK/TCK.h"
namespace TeensyTimerTool
{
TimerGenerator* const TCK = TCK_t::getTimer<uint32_t>;
TimerGenerator* const TCK32 = TCK_t::getTimer<uint32_t>; // same as TCK
TimerGenerator* const TCK64 = TCK_t::getTimer<uint64_t>;
TimerGenerator* const FTM0 = FTM_t<0>::getTimer;
TimerGenerator* const FTM1 = FTM_t<1>::getTimer;
TimerGenerator* const FTM2 = FTM_t<2>::getTimer;
constexpr tick_t tick = &TCK_t::tick;
}
#elif defined(ARDUINO_TEENSY30)
#include "Teensy/FTM/FTM.h"
#include "Teensy/TCK/TCK.h"
namespace TeensyTimerTool
{
TimerGenerator* const TCK = TCK_t::getTimer;
TimerGenerator* const FTM0 = FTM_t<0>::getTimer;
TimerGenerator* const FTM1 = FTM_t<1>::getTimer;
constexpr tick_t tick = &TCK_t::tick;
}
#elif defined(ARDUINO_TEENSYLC)
#include "Teensy/TCK/TCK.h"
namespace TeensyTimerTool
{
TimerGenerator* const TCK = TCK_t::getTimer<uint32_t>;
constexpr tick_t tick = &TCK_t::tick;
}
#endif

@ -0,0 +1,7 @@
#pragma once
#if __has_include("userConfig.h")
#include "userConfig.h"
#else
#include "defaultConfig.h"
#endif

@ -0,0 +1,91 @@
#pragma once
#include "boardDef.h"
namespace TeensyTimerTool
{
//--------------------------------------------------------------------------------------------
// Timer pool defintion
// Add, and sort and remove to define the timer pool. Timers will be allocted from left to right
#if defined(ARDUINO_TEENSY_MICROMOD)
TimerGenerator* const timerPool[] = {GPT1, GPT2, TMR1, TMR2, TMR3, TMR4, TCK};
#elif defined(ARDUINO_TEENSY40)
TimerGenerator* const timerPool[] = {GPT1, GPT2, TMR1, TMR2, TMR3, TMR4, TCK};
#elif defined(ARDUINO_TEENSY41)
TimerGenerator* const timerPool[] = {GPT1, GPT2, TMR1, TMR2, TMR3, TMR4, TCK};
#elif defined(ARDUINO_TEENSY36)
TimerGenerator* const timerPool[] = {FTM0, FTM1, FTM2, FTM3, FTM4, TCK};
#elif defined(ARDUINO_TEENSY35)
TimerGenerator* const timerPool[] = {FTM0, FTM1, FTM2, FTM3, TCK};
#elif defined(ARDUINO_TEENSY31) || defined(ARDUINO_TEENSY32)
TimerGenerator* const timerPool[] = {FTM0, FTM1, FTM2, TCK};
#elif defined(ARDUINO_TEENSY30)
TimerGenerator* const timerPool[] = {FTM0, FTM1, TCK};
#elif defined(ARDUINO_TEENSYLC)
TimerGenerator* const timerPool[] = {TCK};
#elif defined(ESP32)
TimerGenerator* const timerPool[] = {TCK};
#elif defined(UNO)
TimerGenerator* const timerPool[] = {TCK};
#endif
constexpr unsigned timerCnt = sizeof(timerPool) / sizeof(timerPool[0]);
//--------------------------------------------------------------------------------------------
// Default settings for various timers
// TMR (QUAD)
constexpr int TMR_DEFAULT_PSC = PSC_128; // Allowed prescaling values: PSC_1, PSC_2, PSC_4 ... PSC_128, clock = 150MHz
// FTM
constexpr int FTM_DEFAULT_PSC[] = // Allowed prescaling values: PSC_AUTO, PSC_1, PSC_2, PSC_4 ... PSC_128, clock = FBUS
{ // (PSC_AUTO adjusts prescaler to get roughly 2 timer ticks per µs)
/*FTM0*/ PSC_AUTO,
/*FTM1*/ PSC_AUTO,
/*FTM2*/ PSC_AUTO,
/*FTM3*/ PSC_AUTO
};
// GPT & PID
constexpr bool USE_GPT_PIT_150MHz = false;// changes the clock source for GPT and PIT from 24MHz (standard) to 150MHz, might have side effects!
// TCK
constexpr unsigned NR_OF_TCK_TIMERS = 20; // How many TCK timers shall be available
#define YIELD_TYPE YIELD_STANDARD // Select the required yield strategy from the list below
// YIELD_NONE: lib doesn't touch yield. Make sure to call TeensyTimerTool::tick as often as possible
// YIELD_STANDARD: uses the standard yield function and adds a call to TeensyTimerTool::tick(). Lots of overhead in yield...
// YIELD_OPTIMIZED: generate an optimized yield which only calls TeensyTimerTool::Tick() (recommended if you don't use SerialEvents)
//--------------------------------------------------------------------------------------------
// Callback type
// Uncomment if you prefer function pointer callbacks instead of std::function callbacks
// #define PLAIN_VANILLA_CALLBACKS
//--------------------------------------------------------------------------------------------
// Use additionally c++14 user literals (e.g. 3.4s, 50ms ...) for time inputs
// Comment the following line if you don't want this.
#define USE_TIME_LITERALS
//--------------------------------------------------------------------------------------------
// Advanced Features
// Uncomment if you need access to advanced features
// #define ENABLE_ADVANCED_FEATURES
}

@ -0,0 +1,406 @@
// <chrono> -*- C++ -*-
// Copyright (C) 2008-2015 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library. This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, 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 General Public License for more details.
// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.
// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
// <http://www.gnu.org/licenses/>.
#pragma once
#include <chrono>
#include <limits>
#include <ratio>
#include <type_traits>
using std::common_type;
using std::enable_if;
using std::is_convertible;
using std::ratio;
using std::ratio_divide;
namespace TeensyTimerTool
{
template <typename _Rep, typename _Period = ratio<1>>
struct frequency;
template <typename _CT, typename _Period1, typename _Period2>
struct __frequency_common_type_wrapper
{
private:
typedef std::__static_gcd<_Period1::num, _Period2::num> __gcd_num;
typedef std::__static_gcd<_Period1::den, _Period2::den> __gcd_den;
typedef typename _CT::type __cr;
typedef ratio<__gcd_num::value,
(_Period1::den / __gcd_den::value) * _Period2::den>
__r;
public:
typedef std::__success_type<TeensyTimerTool::frequency<__cr, __r>> type;
};
template <typename _Period1, typename _Period2>
struct __frequency_common_type_wrapper<std::__failure_type, _Period1, _Period2>
{
typedef std::__failure_type type;
};
}
namespace std
{
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
struct common_type<TeensyTimerTool::frequency<_Rep1, _Period1>, TeensyTimerTool::frequency<_Rep2, _Period2>>
: public TeensyTimerTool::__frequency_common_type_wrapper<typename __member_type_wrapper<std::common_type<_Rep1, _Rep2>>::type, _Period1, _Period2>::type
{
};
}
namespace TeensyTimerTool
{
using namespace std::chrono;
// Primary template for frequency_cast impl.
template <typename _ToDur, typename _CF, typename _CR,
bool _NumIsOne = false, bool _DenIsOne = false>
struct __frequency_cast_impl
{
template <typename _Rep, typename _Period>
static constexpr _ToDur
__cast(const frequency<_Rep, _Period>& __d)
{
typedef typename _ToDur::rep __to_rep;
return _ToDur(static_cast<__to_rep>(static_cast<_CR>(__d.count()) * static_cast<_CR>(_CF::num) / static_cast<_CR>(_CF::den)));
}
};
template <typename _ToDur, typename _CF, typename _CR>
struct __frequency_cast_impl<_ToDur, _CF, _CR, true, true>
{
template <typename _Rep, typename _Period>
static constexpr _ToDur
__cast(const frequency<_Rep, _Period>& __d)
{
typedef typename _ToDur::rep __to_rep;
return _ToDur(static_cast<__to_rep>(__d.count()));
}
};
template <typename _ToDur, typename _CF, typename _CR>
struct __frequency_cast_impl<_ToDur, _CF, _CR, true, false>
{
template <typename _Rep, typename _Period>
static constexpr _ToDur
__cast(const frequency<_Rep, _Period>& __d)
{
typedef typename _ToDur::rep __to_rep;
return _ToDur(static_cast<__to_rep>(
static_cast<_CR>(__d.count()) / static_cast<_CR>(_CF::den)));
}
};
template <typename _ToDur, typename _CF, typename _CR>
struct __frequency_cast_impl<_ToDur, _CF, _CR, false, true>
{
template <typename _Rep, typename _Period>
static constexpr _ToDur
__cast(const frequency<_Rep, _Period>& __d)
{
typedef typename _ToDur::rep __to_rep;
return _ToDur(static_cast<__to_rep>(
static_cast<_CR>(__d.count()) * static_cast<_CR>(_CF::num)));
}
};
template <typename _Tp>
struct __is_frequency
: std::false_type
{
};
template <typename _Rep, typename _Period>
struct __is_frequency<frequency<_Rep, _Period>>
: std::true_type
{
};
/// duration_cast
template <typename _ToDur, typename _Rep, typename _Period>
constexpr typename enable_if<__is_frequency<_ToDur>::value, _ToDur>::type duration_cast(const frequency<_Rep, _Period>& __d)
{
typedef typename _ToDur::period __to_period;
typedef typename _ToDur::rep __to_rep;
typedef ratio_divide<_Period, __to_period> __cf;
typedef typename common_type<__to_rep, _Rep, intmax_t>::type __cr;
typedef __frequency_cast_impl<_ToDur, __cf, __cr, __cf::num == 1, __cf::den == 1> __dc;
return __dc::__cast(__d);
}
/// frequency
template <typename _Rep, typename _Period>
struct frequency
{
typedef _Rep rep;
typedef _Period period;
static_assert(!__is_frequency<_Rep>::value, "rep cannot be a frequency");
static_assert(std::chrono::__is_ratio<_Period>::value, "period must be a specialization of ratio");
static_assert(_Period::num > 0, "period must be positive");
// 20.11.5.1 construction / copy / destroy
constexpr frequency() = default;
// NB: Make constexpr implicit. This cannot be explicitly
// constexpr, as any UDT that is not a literal type with a
// constexpr copy constructor will be ill-formed.
frequency(const frequency&) = default;
template <typename _Rep2, typename = typename enable_if<is_convertible<_Rep2, rep>::value && (std::chrono::treat_as_floating_point<rep>::value || !std::chrono::treat_as_floating_point<_Rep2>::value)>::type>
constexpr explicit frequency(const _Rep2& __rep)
: __r(static_cast<rep>(__rep))
{
}
template <typename _Rep2, typename _Period2, typename = typename enable_if<treat_as_floating_point<rep>::value || (ratio_divide<_Period2, period>::den == 1 && !treat_as_floating_point<_Rep2>::value)>::type>
constexpr frequency(const frequency<_Rep2, _Period2>& __d)
: __r(duration_cast<frequency>(__d).count()) {}
~frequency() = default;
frequency& operator=(const frequency&) = default;
// 20.11.5.2 observer
constexpr rep count() const { return __r; }
constexpr frequency operator+() const { return *this; }
constexpr frequency operator-() const { return frequency(-__r); }
frequency& operator++()
{
++__r;
return *this;
}
frequency operator++(int)
{
return frequency(__r++);
}
frequency& operator--()
{
--__r;
return *this;
}
frequency
operator--(int)
{
return frequency(__r--);
}
frequency&
operator+=(const frequency& __d)
{
__r += __d.count();
return *this;
}
frequency&
operator-=(const frequency& __d)
{
__r -= __d.count();
return *this;
}
frequency&
operator*=(const rep& __rhs)
{
__r *= __rhs;
return *this;
}
frequency&
operator/=(const rep& __rhs)
{
__r /= __rhs;
return *this;
}
// DR 934.
template <typename _Rep2 = rep>
typename enable_if<!treat_as_floating_point<_Rep2>::value,
frequency&>::type
operator%=(const rep& __rhs)
{
__r %= __rhs;
return *this;
}
template <typename _Rep2 = rep>
typename enable_if<!treat_as_floating_point<_Rep2>::value,
frequency&>::type
operator%=(const frequency& __d)
{
__r %= __d.count();
return *this;
}
// 20.11.5.4 special values
static constexpr frequency
zero()
{
return frequency(duration_values<rep>::zero());
}
static constexpr frequency
min()
{
return frequency(duration_values<rep>::min());
}
static constexpr frequency
max()
{
return frequency(duration_values<rep>::max());
}
private:
rep __r;
};
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr typename common_type<frequency<_Rep1, _Period1>, frequency<_Rep2, _Period2>>::type operator+(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __cd;
return __cd(__cd(__lhs).count() + __cd(__rhs).count());
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr typename common_type<frequency<_Rep1, _Period1>, frequency<_Rep2, _Period2>>::type operator-(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __cd;
return __cd(__cd(__lhs).count() - __cd(__rhs).count());
}
template <typename _Rep1, typename _Period, typename _Rep2>
constexpr frequency<typename __common_rep_type<_Rep1, _Rep2>::type, _Period> operator*(const frequency<_Rep1, _Period>& __d, const _Rep2& __s)
{
typedef frequency<typename common_type<_Rep1, _Rep2>::type, _Period> __cd;
return __cd(__cd(__d).count() * __s);
}
template <typename _Rep1, typename _Rep2, typename _Period>
constexpr frequency<typename __common_rep_type<_Rep2, _Rep1>::type, _Period> operator*(const _Rep1& __s, const frequency<_Rep2, _Period>& __d)
{
return __d * __s;
}
template <typename _Rep1, typename _Period, typename _Rep2>
constexpr frequency<typename __common_rep_type<_Rep1, typename enable_if<!__is_frequency<_Rep2>::value, _Rep2>::type>::type, _Period> operator/(const frequency<_Rep1, _Period>& __d, const _Rep2& __s)
{
typedef frequency<typename common_type<_Rep1, _Rep2>::type, _Period> __cd;
return __cd(__cd(__d).count() / __s);
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr typename common_type<_Rep1, _Rep2>::type operator/(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __cd;
return __cd(__lhs).count() / __cd(__rhs).count();
}
// DR 934.
template <typename _Rep1, typename _Period, typename _Rep2>
constexpr frequency<typename __common_rep_type<_Rep1, typename enable_if<!__is_frequency<_Rep2>::value, _Rep2>::type>::type, _Period> operator%(const frequency<_Rep1, _Period>& __d, const _Rep2& __s)
{
typedef frequency<typename common_type<_Rep1, _Rep2>::type, _Period> __cd;
return __cd(__cd(__d).count() % __s);
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr typename common_type<frequency<_Rep1, _Period1>, frequency<_Rep2, _Period2>>::type operator%(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __cd;
return __cd(__cd(__lhs).count() % __cd(__rhs).count());
}
// comparisons
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator==(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __ct;
return __ct(__lhs).count() == __ct(__rhs).count();
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator<(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
typedef frequency<_Rep1, _Period1> __dur1;
typedef frequency<_Rep2, _Period2> __dur2;
typedef typename common_type<__dur1, __dur2>::type __ct;
return __ct(__lhs).count() < __ct(__rhs).count();
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator!=(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
return !(__lhs == __rhs);
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator<=(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
return !(__rhs < __lhs);
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator>(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
return __rhs < __lhs;
}
template <typename _Rep1, typename _Period1, typename _Rep2, typename _Period2>
constexpr bool operator>=(const frequency<_Rep1, _Period1>& __lhs, const frequency<_Rep2, _Period2>& __rhs)
{
return !(__lhs < __rhs);
}
using hertz = frequency<float>;
using kilohertz = frequency<float, std::kilo>;
using megahertz = frequency<float, std::mega>;
using gigahertz = frequency<float, std::giga>;
constexpr hertz operator""_Hz(long double hz) { return hertz{hz}; }
constexpr hertz operator""_Hz(uint64_t hz) { return hertz{hz}; }
constexpr kilohertz operator""_kHz(long double kHz) { return kilohertz{kHz}; }
constexpr kilohertz operator""_kHz(uint64_t kHz) { return kilohertz{kHz}; }
constexpr megahertz operator""_MHz(long double MHz) { return megahertz{MHz}; }
constexpr megahertz operator""_MHz(uint64_t MHz) { return megahertz{MHz}; }
constexpr gigahertz operator""_GHz(long double GHz) { return gigahertz{GHz}; }
constexpr gigahertz operator""_GHz(uint64_t GHz) { return gigahertz{GHz}; }
}

@ -0,0 +1,66 @@
#pragma once
#include "ErrorHandling/error_codes.h"
#include "baseTimer.h"
#include "type_traits"
namespace TeensyTimerTool
{
class OneShotTimer : public BaseTimer
{
public:
inline OneShotTimer(TimerGenerator* generator = nullptr);
inline errorCode begin(callback_t cb);
template <typename T> errorCode trigger(T delay);
template <typename T> errorCode triggerDirect(T reload);
template <typename T> errorCode getTriggerReload(float delay, T* reload);
#if defined(USE_TIME_LITERALS)
template <typename T, typename ratio>
errorCode trigger(duration<T, ratio> _delay)
{
T delay = duration_cast<microseconds>(_delay).count();
return trigger(delay);
}
#endif
};
// Implementation ================================================
OneShotTimer::OneShotTimer(TimerGenerator* generator)
: BaseTimer(generator, false)
{}
errorCode OneShotTimer::begin(callback_t callback)
{
return BaseTimer::begin(callback, 0, false);
}
template <typename T>
errorCode OneShotTimer::trigger(T delay)
{
static_assert(std::is_integral<T>() || std::is_floating_point<T>(), "Only floating point or integral types allowed");
errorCode result;
if (std::is_floating_point<T>())
result = timerChannel->trigger((float)delay);
else
result = timerChannel->trigger((uint32_t)delay);
return result;
}
template <typename T>
errorCode OneShotTimer::triggerDirect(T reload)
{
return timerChannel->triggerDirect(reload);
}
template <typename T>
errorCode OneShotTimer::getTriggerReload(float delay, T* reload)
{
return timerChannel->getTriggerReload(delay, reload);
}
}

@ -0,0 +1,22 @@
#pragma once
#include "baseTimer.h"
namespace TeensyTimerTool
{
class PeriodicTimer : public BaseTimer
{
public:
PeriodicTimer(TimerGenerator* generator = nullptr)
: BaseTimer(generator, true) {}
template <class T, std::enable_if_t<std::is_arithmetic<T>::value, int>* = nullptr>
errorCode setPeriod(T p) { return postError(timerChannel->setPeriod((float)p)); }
template <class T, std::enable_if_t<std::is_arithmetic<T>::value, int>* = nullptr>
errorCode setNextPeriod(T p) { return postError(timerChannel->setNextPeriod((float)p)); }
};
// IMPLEMENTATION =====================================================================
}

@ -0,0 +1,34 @@
#pragma once
#include "ErrorHandling/error_codes.h"
#include "ITimerChannel.h"
#include "baseTimer.h"
#include "types.h"
namespace TeensyTimerTool
{
//class [[deprecated("Use PeriodicTimer or OneShotTimer instead")]] Timer : public BaseTimer
class Timer : public BaseTimer
{
public:
Timer(TimerGenerator* gen = nullptr);
inline errorCode beginPeriodic(callback_t cb, uint32_t period)
{
isPeriodic = true;
return BaseTimer::begin(cb, period, true);
}
inline errorCode beginOneShot(callback_t cb)
{
isPeriodic = false;
return BaseTimer::begin(cb, 0, false);
}
inline void trigger(uint32_t delay);
};
// IMPLEMENTATION =======================================================
void Timer::trigger(const uint32_t delay)
{
timerChannel->trigger(delay);
}
}

@ -0,0 +1,30 @@
#pragma once
#include "ErrorHandling/error_codes.h"
#include "config.h"
#if not defined(PLAIN_VANILLA_CALLBACKS)
#include <functional>
inline void std::__throw_bad_function_call()
{
while (1) {} // do whatever you want to do instead of an exception
}
namespace TeensyTimerTool
{
using callback_t = std::function<void(void)>;
using errorFunc_t = std::function<void(errorCode)>;
extern void attachErrFunc(errorFunc_t);
extern errorCode postError(errorCode);
}
#else
namespace TeensyTimerTool
{
using callback_t = void (*)();
using errorFunc_t = void (*)(errorCode);
extern void attachErrFunc(errorFunc_t);
extern errorCode postError(errorCode);
}
#endif
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