jlj-qmk/quantum/quantum.c
Joe Wasson 5987f67989 Add TX Bolt protocol support for Stenography
Requires virtser; Allows QMK to speak the TX BOlt protocol used by stenography machines and software (such as Plover). The upside is that Plover can be configured to listen only to TX Bolt allow the keyboard to switch layers without need to enable/disable the Plover software, or to have a second non-Steno keyboard work concurrently.
2017-07-27 16:10:36 -04:00

1106 lines
27 KiB
C

/* Copyright 2016-2017 Jack Humbert
*
* 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 2 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, see <http://www.gnu.org/licenses/>.
*/
#include "quantum.h"
#ifdef PROTOCOL_LUFA
#include "outputselect.h"
#endif
#ifndef TAPPING_TERM
#define TAPPING_TERM 200
#endif
#include "backlight.h"
extern backlight_config_t backlight_config;
#ifdef FAUXCLICKY_ENABLE
#include "fauxclicky.h"
#endif
#ifdef AUDIO_ENABLE
#ifndef GOODBYE_SONG
#define GOODBYE_SONG SONG(GOODBYE_SOUND)
#endif
#ifndef AG_NORM_SONG
#define AG_NORM_SONG SONG(AG_NORM_SOUND)
#endif
#ifndef AG_SWAP_SONG
#define AG_SWAP_SONG SONG(AG_SWAP_SOUND)
#endif
#ifndef DEFAULT_LAYER_SONGS
#define DEFAULT_LAYER_SONGS { }
#endif
float goodbye_song[][2] = GOODBYE_SONG;
float ag_norm_song[][2] = AG_NORM_SONG;
float ag_swap_song[][2] = AG_SWAP_SONG;
float default_layer_songs[][16][2] = DEFAULT_LAYER_SONGS;
#endif
static void do_code16 (uint16_t code, void (*f) (uint8_t)) {
switch (code) {
case QK_MODS ... QK_MODS_MAX:
break;
default:
return;
}
if (code & QK_LCTL)
f(KC_LCTL);
if (code & QK_LSFT)
f(KC_LSFT);
if (code & QK_LALT)
f(KC_LALT);
if (code & QK_LGUI)
f(KC_LGUI);
if (code < QK_RMODS_MIN) return;
if (code & QK_RCTL)
f(KC_RCTL);
if (code & QK_RSFT)
f(KC_RSFT);
if (code & QK_RALT)
f(KC_RALT);
if (code & QK_RGUI)
f(KC_RGUI);
}
static inline void qk_register_weak_mods(uint8_t kc) {
add_weak_mods(MOD_BIT(kc));
send_keyboard_report();
}
static inline void qk_unregister_weak_mods(uint8_t kc) {
del_weak_mods(MOD_BIT(kc));
send_keyboard_report();
}
static inline void qk_register_mods(uint8_t kc) {
add_weak_mods(MOD_BIT(kc));
send_keyboard_report();
}
static inline void qk_unregister_mods(uint8_t kc) {
del_weak_mods(MOD_BIT(kc));
send_keyboard_report();
}
void register_code16 (uint16_t code) {
if (IS_MOD(code) || code == KC_NO) {
do_code16 (code, qk_register_mods);
} else {
do_code16 (code, qk_register_weak_mods);
}
register_code (code);
}
void unregister_code16 (uint16_t code) {
unregister_code (code);
if (IS_MOD(code) || code == KC_NO) {
do_code16 (code, qk_unregister_mods);
} else {
do_code16 (code, qk_unregister_weak_mods);
}
}
__attribute__ ((weak))
bool process_action_kb(keyrecord_t *record) {
return true;
}
__attribute__ ((weak))
bool process_record_kb(uint16_t keycode, keyrecord_t *record) {
return process_record_user(keycode, record);
}
__attribute__ ((weak))
bool process_record_user(uint16_t keycode, keyrecord_t *record) {
return true;
}
void reset_keyboard(void) {
clear_keyboard();
#if defined(AUDIO_ENABLE) || (defined(MIDI_ENABLE) && defined(MIDI_ENABLE_BASIC))
music_all_notes_off();
uint16_t timer_start = timer_read();
PLAY_SONG(goodbye_song);
shutdown_user();
while(timer_elapsed(timer_start) < 250)
wait_ms(1);
stop_all_notes();
#else
wait_ms(250);
#endif
#ifdef CATERINA_BOOTLOADER
*(uint16_t *)0x0800 = 0x7777; // these two are a-star-specific
#endif
bootloader_jump();
}
// Shift / paren setup
#ifndef LSPO_KEY
#define LSPO_KEY KC_9
#endif
#ifndef RSPC_KEY
#define RSPC_KEY KC_0
#endif
static bool shift_interrupted[2] = {0, 0};
static uint16_t scs_timer[2] = {0, 0};
bool process_record_quantum(keyrecord_t *record) {
/* This gets the keycode from the key pressed */
keypos_t key = record->event.key;
uint16_t keycode;
#if !defined(NO_ACTION_LAYER) && defined(PREVENT_STUCK_MODIFIERS)
/* TODO: Use store_or_get_action() or a similar function. */
if (!disable_action_cache) {
uint8_t layer;
if (record->event.pressed) {
layer = layer_switch_get_layer(key);
update_source_layers_cache(key, layer);
} else {
layer = read_source_layers_cache(key);
}
keycode = keymap_key_to_keycode(layer, key);
} else
#endif
keycode = keymap_key_to_keycode(layer_switch_get_layer(key), key);
// This is how you use actions here
// if (keycode == KC_LEAD) {
// action_t action;
// action.code = ACTION_DEFAULT_LAYER_SET(0);
// process_action(record, action);
// return false;
// }
if (!(
process_record_kb(keycode, record) &&
#if defined(MIDI_ENABLE) && defined(MIDI_ADVANCED)
process_midi(keycode, record) &&
#endif
#ifdef AUDIO_ENABLE
process_audio(keycode, record) &&
#endif
#ifdef STENO_ENABLE
process_steno(keycode, record) &&
#endif
#if defined(AUDIO_ENABLE) || (defined(MIDI_ENABLE) && defined(MIDI_BASIC))
process_music(keycode, record) &&
#endif
#ifdef TAP_DANCE_ENABLE
process_tap_dance(keycode, record) &&
#endif
#ifndef DISABLE_LEADER
process_leader(keycode, record) &&
#endif
#ifndef DISABLE_CHORDING
process_chording(keycode, record) &&
#endif
#ifdef COMBO_ENABLE
process_combo(keycode, record) &&
#endif
#ifdef UNICODE_ENABLE
process_unicode(keycode, record) &&
#endif
#ifdef UCIS_ENABLE
process_ucis(keycode, record) &&
#endif
#ifdef PRINTING_ENABLE
process_printer(keycode, record) &&
#endif
#ifdef UNICODEMAP_ENABLE
process_unicode_map(keycode, record) &&
#endif
true)) {
return false;
}
// Shift / paren setup
switch(keycode) {
case RESET:
if (record->event.pressed) {
reset_keyboard();
}
return false;
break;
case DEBUG:
if (record->event.pressed) {
print("\nDEBUG: enabled.\n");
debug_enable = true;
}
return false;
break;
#ifdef FAUXCLICKY_ENABLE
case FC_TOG:
if (record->event.pressed) {
FAUXCLICKY_TOGGLE;
}
return false;
break;
case FC_ON:
if (record->event.pressed) {
FAUXCLICKY_ON;
}
return false;
break;
case FC_OFF:
if (record->event.pressed) {
FAUXCLICKY_OFF;
}
return false;
break;
#endif
#ifdef RGBLIGHT_ENABLE
case RGB_TOG:
if (record->event.pressed) {
rgblight_toggle();
}
return false;
break;
case RGB_MOD:
if (record->event.pressed) {
rgblight_step();
}
return false;
break;
case RGB_HUI:
if (record->event.pressed) {
rgblight_increase_hue();
}
return false;
break;
case RGB_HUD:
if (record->event.pressed) {
rgblight_decrease_hue();
}
return false;
break;
case RGB_SAI:
if (record->event.pressed) {
rgblight_increase_sat();
}
return false;
break;
case RGB_SAD:
if (record->event.pressed) {
rgblight_decrease_sat();
}
return false;
break;
case RGB_VAI:
if (record->event.pressed) {
rgblight_increase_val();
}
return false;
break;
case RGB_VAD:
if (record->event.pressed) {
rgblight_decrease_val();
}
return false;
break;
#endif
#ifdef PROTOCOL_LUFA
case OUT_AUTO:
if (record->event.pressed) {
set_output(OUTPUT_AUTO);
}
return false;
break;
case OUT_USB:
if (record->event.pressed) {
set_output(OUTPUT_USB);
}
return false;
break;
#ifdef BLUETOOTH_ENABLE
case OUT_BT:
if (record->event.pressed) {
set_output(OUTPUT_BLUETOOTH);
}
return false;
break;
#endif
#endif
case MAGIC_SWAP_CONTROL_CAPSLOCK ... MAGIC_TOGGLE_NKRO:
if (record->event.pressed) {
// MAGIC actions (BOOTMAGIC without the boot)
if (!eeconfig_is_enabled()) {
eeconfig_init();
}
/* keymap config */
keymap_config.raw = eeconfig_read_keymap();
switch (keycode)
{
case MAGIC_SWAP_CONTROL_CAPSLOCK:
keymap_config.swap_control_capslock = true;
break;
case MAGIC_CAPSLOCK_TO_CONTROL:
keymap_config.capslock_to_control = true;
break;
case MAGIC_SWAP_LALT_LGUI:
keymap_config.swap_lalt_lgui = true;
break;
case MAGIC_SWAP_RALT_RGUI:
keymap_config.swap_ralt_rgui = true;
break;
case MAGIC_NO_GUI:
keymap_config.no_gui = true;
break;
case MAGIC_SWAP_GRAVE_ESC:
keymap_config.swap_grave_esc = true;
break;
case MAGIC_SWAP_BACKSLASH_BACKSPACE:
keymap_config.swap_backslash_backspace = true;
break;
case MAGIC_HOST_NKRO:
keymap_config.nkro = true;
break;
case MAGIC_SWAP_ALT_GUI:
keymap_config.swap_lalt_lgui = true;
keymap_config.swap_ralt_rgui = true;
#ifdef AUDIO_ENABLE
PLAY_SONG(ag_swap_song);
#endif
break;
case MAGIC_UNSWAP_CONTROL_CAPSLOCK:
keymap_config.swap_control_capslock = false;
break;
case MAGIC_UNCAPSLOCK_TO_CONTROL:
keymap_config.capslock_to_control = false;
break;
case MAGIC_UNSWAP_LALT_LGUI:
keymap_config.swap_lalt_lgui = false;
break;
case MAGIC_UNSWAP_RALT_RGUI:
keymap_config.swap_ralt_rgui = false;
break;
case MAGIC_UNNO_GUI:
keymap_config.no_gui = false;
break;
case MAGIC_UNSWAP_GRAVE_ESC:
keymap_config.swap_grave_esc = false;
break;
case MAGIC_UNSWAP_BACKSLASH_BACKSPACE:
keymap_config.swap_backslash_backspace = false;
break;
case MAGIC_UNHOST_NKRO:
keymap_config.nkro = false;
break;
case MAGIC_UNSWAP_ALT_GUI:
keymap_config.swap_lalt_lgui = false;
keymap_config.swap_ralt_rgui = false;
#ifdef AUDIO_ENABLE
PLAY_SONG(ag_norm_song);
#endif
break;
case MAGIC_TOGGLE_NKRO:
keymap_config.nkro = !keymap_config.nkro;
break;
default:
break;
}
eeconfig_update_keymap(keymap_config.raw);
clear_keyboard(); // clear to prevent stuck keys
return false;
}
break;
case KC_LSPO: {
if (record->event.pressed) {
shift_interrupted[0] = false;
scs_timer[0] = timer_read ();
register_mods(MOD_BIT(KC_LSFT));
}
else {
#ifdef DISABLE_SPACE_CADET_ROLLOVER
if (get_mods() & MOD_BIT(KC_RSFT)) {
shift_interrupted[0] = true;
shift_interrupted[1] = true;
}
#endif
if (!shift_interrupted[0] && timer_elapsed(scs_timer[0]) < TAPPING_TERM) {
register_code(LSPO_KEY);
unregister_code(LSPO_KEY);
}
unregister_mods(MOD_BIT(KC_LSFT));
}
return false;
// break;
}
case KC_RSPC: {
if (record->event.pressed) {
shift_interrupted[1] = false;
scs_timer[1] = timer_read ();
register_mods(MOD_BIT(KC_RSFT));
}
else {
#ifdef DISABLE_SPACE_CADET_ROLLOVER
if (get_mods() & MOD_BIT(KC_LSFT)) {
shift_interrupted[0] = true;
shift_interrupted[1] = true;
}
#endif
if (!shift_interrupted[1] && timer_elapsed(scs_timer[1]) < TAPPING_TERM) {
register_code(RSPC_KEY);
unregister_code(RSPC_KEY);
}
unregister_mods(MOD_BIT(KC_RSFT));
}
return false;
// break;
}
case GRAVE_ESC: {
void (*method)(uint8_t) = (record->event.pressed) ? &add_key : &del_key;
uint8_t shifted = get_mods() & ((MOD_BIT(KC_LSHIFT)|MOD_BIT(KC_RSHIFT)
|MOD_BIT(KC_LGUI)|MOD_BIT(KC_RGUI)));
method(shifted ? KC_GRAVE : KC_ESCAPE);
send_keyboard_report();
}
default: {
shift_interrupted[0] = true;
shift_interrupted[1] = true;
break;
}
}
return process_action_kb(record);
}
__attribute__ ((weak))
const bool ascii_to_shift_lut[0x80] PROGMEM = {
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 1, 1, 1, 1, 1, 1, 0,
1, 1, 1, 1, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 1, 0, 1, 0, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 0, 0, 0, 1, 1,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 1, 1, 1, 1, 0
};
__attribute__ ((weak))
const uint8_t ascii_to_keycode_lut[0x80] PROGMEM = {
0, 0, 0, 0, 0, 0, 0, 0,
KC_BSPC, KC_TAB, KC_ENT, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, KC_ESC, 0, 0, 0, 0,
KC_SPC, KC_1, KC_QUOT, KC_3, KC_4, KC_5, KC_7, KC_QUOT,
KC_9, KC_0, KC_8, KC_EQL, KC_COMM, KC_MINS, KC_DOT, KC_SLSH,
KC_0, KC_1, KC_2, KC_3, KC_4, KC_5, KC_6, KC_7,
KC_8, KC_9, KC_SCLN, KC_SCLN, KC_COMM, KC_EQL, KC_DOT, KC_SLSH,
KC_2, KC_A, KC_B, KC_C, KC_D, KC_E, KC_F, KC_G,
KC_H, KC_I, KC_J, KC_K, KC_L, KC_M, KC_N, KC_O,
KC_P, KC_Q, KC_R, KC_S, KC_T, KC_U, KC_V, KC_W,
KC_X, KC_Y, KC_Z, KC_LBRC, KC_BSLS, KC_RBRC, KC_6, KC_MINS,
KC_GRV, KC_A, KC_B, KC_C, KC_D, KC_E, KC_F, KC_G,
KC_H, KC_I, KC_J, KC_K, KC_L, KC_M, KC_N, KC_O,
KC_P, KC_Q, KC_R, KC_S, KC_T, KC_U, KC_V, KC_W,
KC_X, KC_Y, KC_Z, KC_LBRC, KC_BSLS, KC_RBRC, KC_GRV, KC_DEL
};
void send_string(const char *str) {
send_string_with_delay(str, 0);
}
void send_string_with_delay(const char *str, uint8_t interval) {
while (1) {
uint8_t keycode;
uint8_t ascii_code = pgm_read_byte(str);
if (!ascii_code) break;
keycode = pgm_read_byte(&ascii_to_keycode_lut[ascii_code]);
if (pgm_read_byte(&ascii_to_shift_lut[ascii_code])) {
register_code(KC_LSFT);
register_code(keycode);
unregister_code(keycode);
unregister_code(KC_LSFT);
}
else {
register_code(keycode);
unregister_code(keycode);
}
++str;
// interval
{ uint8_t ms = interval; while (ms--) wait_ms(1); }
}
}
void set_single_persistent_default_layer(uint8_t default_layer) {
#ifdef AUDIO_ENABLE
PLAY_SONG(default_layer_songs[default_layer]);
#endif
eeconfig_update_default_layer(1U<<default_layer);
default_layer_set(1U<<default_layer);
}
void update_tri_layer(uint8_t layer1, uint8_t layer2, uint8_t layer3) {
if (IS_LAYER_ON(layer1) && IS_LAYER_ON(layer2)) {
layer_on(layer3);
} else {
layer_off(layer3);
}
}
void tap_random_base64(void) {
#if defined(__AVR_ATmega32U4__)
uint8_t key = (TCNT0 + TCNT1 + TCNT3 + TCNT4) % 64;
#else
uint8_t key = rand() % 64;
#endif
switch (key) {
case 0 ... 25:
register_code(KC_LSFT);
register_code(key + KC_A);
unregister_code(key + KC_A);
unregister_code(KC_LSFT);
break;
case 26 ... 51:
register_code(key - 26 + KC_A);
unregister_code(key - 26 + KC_A);
break;
case 52:
register_code(KC_0);
unregister_code(KC_0);
break;
case 53 ... 61:
register_code(key - 53 + KC_1);
unregister_code(key - 53 + KC_1);
break;
case 62:
register_code(KC_LSFT);
register_code(KC_EQL);
unregister_code(KC_EQL);
unregister_code(KC_LSFT);
break;
case 63:
register_code(KC_SLSH);
unregister_code(KC_SLSH);
break;
}
}
void matrix_init_quantum() {
#ifdef BACKLIGHT_ENABLE
backlight_init_ports();
#endif
#ifdef AUDIO_ENABLE
audio_init();
#endif
matrix_init_kb();
}
void matrix_scan_quantum() {
#ifdef AUDIO_ENABLE
matrix_scan_music();
#endif
#ifdef TAP_DANCE_ENABLE
matrix_scan_tap_dance();
#endif
#ifdef COMBO_ENABLE
matrix_scan_combo();
#endif
#if defined(BACKLIGHT_ENABLE) && defined(BACKLIGHT_PIN)
backlight_task();
#endif
matrix_scan_kb();
}
#if defined(BACKLIGHT_ENABLE) && defined(BACKLIGHT_PIN)
static const uint8_t backlight_pin = BACKLIGHT_PIN;
#if BACKLIGHT_PIN == B7
# define COM1x1 COM1C1
# define OCR1x OCR1C
#elif BACKLIGHT_PIN == B6
# define COM1x1 COM1B1
# define OCR1x OCR1B
#elif BACKLIGHT_PIN == B5
# define COM1x1 COM1A1
# define OCR1x OCR1A
#else
# define NO_BACKLIGHT_CLOCK
#endif
#ifndef BACKLIGHT_ON_STATE
#define BACKLIGHT_ON_STATE 0
#endif
__attribute__ ((weak))
void backlight_init_ports(void)
{
// Setup backlight pin as output and output to on state.
// DDRx |= n
_SFR_IO8((backlight_pin >> 4) + 1) |= _BV(backlight_pin & 0xF);
#if BACKLIGHT_ON_STATE == 0
// PORTx &= ~n
_SFR_IO8((backlight_pin >> 4) + 2) &= ~_BV(backlight_pin & 0xF);
#else
// PORTx |= n
_SFR_IO8((backlight_pin >> 4) + 2) |= _BV(backlight_pin & 0xF);
#endif
#ifndef NO_BACKLIGHT_CLOCK
// Use full 16-bit resolution.
ICR1 = 0xFFFF;
// I could write a wall of text here to explain... but TL;DW
// Go read the ATmega32u4 datasheet.
// And this: http://blog.saikoled.com/post/43165849837/secret-konami-cheat-code-to-high-resolution-pwm-on
// Pin PB7 = OCR1C (Timer 1, Channel C)
// Compare Output Mode = Clear on compare match, Channel C = COM1C1=1 COM1C0=0
// (i.e. start high, go low when counter matches.)
// WGM Mode 14 (Fast PWM) = WGM13=1 WGM12=1 WGM11=1 WGM10=0
// Clock Select = clk/1 (no prescaling) = CS12=0 CS11=0 CS10=1
TCCR1A = _BV(COM1x1) | _BV(WGM11); // = 0b00001010;
TCCR1B = _BV(WGM13) | _BV(WGM12) | _BV(CS10); // = 0b00011001;
#endif
backlight_init();
#ifdef BACKLIGHT_BREATHING
breathing_defaults();
#endif
}
__attribute__ ((weak))
void backlight_set(uint8_t level)
{
// Prevent backlight blink on lowest level
// #if BACKLIGHT_ON_STATE == 0
// // PORTx &= ~n
// _SFR_IO8((backlight_pin >> 4) + 2) &= ~_BV(backlight_pin & 0xF);
// #else
// // PORTx |= n
// _SFR_IO8((backlight_pin >> 4) + 2) |= _BV(backlight_pin & 0xF);
// #endif
if ( level == 0 ) {
#ifndef NO_BACKLIGHT_CLOCK
// Turn off PWM control on backlight pin, revert to output low.
TCCR1A &= ~(_BV(COM1x1));
OCR1x = 0x0;
#else
// #if BACKLIGHT_ON_STATE == 0
// // PORTx |= n
// _SFR_IO8((backlight_pin >> 4) + 2) |= _BV(backlight_pin & 0xF);
// #else
// // PORTx &= ~n
// _SFR_IO8((backlight_pin >> 4) + 2) &= ~_BV(backlight_pin & 0xF);
// #endif
#endif
}
#ifndef NO_BACKLIGHT_CLOCK
else if ( level == BACKLIGHT_LEVELS ) {
// Turn on PWM control of backlight pin
TCCR1A |= _BV(COM1x1);
// Set the brightness
OCR1x = 0xFFFF;
}
else {
// Turn on PWM control of backlight pin
TCCR1A |= _BV(COM1x1);
// Set the brightness
OCR1x = 0xFFFF >> ((BACKLIGHT_LEVELS - level) * ((BACKLIGHT_LEVELS + 1) / 2));
}
#endif
#ifdef BACKLIGHT_BREATHING
breathing_intensity_default();
#endif
}
uint8_t backlight_tick = 0;
void backlight_task(void) {
#ifdef NO_BACKLIGHT_CLOCK
if ((0xFFFF >> ((BACKLIGHT_LEVELS - backlight_config.level) * ((BACKLIGHT_LEVELS + 1) / 2))) & (1 << backlight_tick)) {
#if BACKLIGHT_ON_STATE == 0
// PORTx &= ~n
_SFR_IO8((backlight_pin >> 4) + 2) &= ~_BV(backlight_pin & 0xF);
#else
// PORTx |= n
_SFR_IO8((backlight_pin >> 4) + 2) |= _BV(backlight_pin & 0xF);
#endif
} else {
#if BACKLIGHT_ON_STATE == 0
// PORTx |= n
_SFR_IO8((backlight_pin >> 4) + 2) |= _BV(backlight_pin & 0xF);
#else
// PORTx &= ~n
_SFR_IO8((backlight_pin >> 4) + 2) &= ~_BV(backlight_pin & 0xF);
#endif
}
backlight_tick = (backlight_tick + 1) % 16;
#endif
}
#ifdef BACKLIGHT_BREATHING
#define BREATHING_NO_HALT 0
#define BREATHING_HALT_OFF 1
#define BREATHING_HALT_ON 2
static uint8_t breath_intensity;
static uint8_t breath_speed;
static uint16_t breathing_index;
static uint8_t breathing_halt;
void breathing_enable(void)
{
if (get_backlight_level() == 0)
{
breathing_index = 0;
}
else
{
// Set breathing_index to be at the midpoint (brightest point)
breathing_index = 0x20 << breath_speed;
}
breathing_halt = BREATHING_NO_HALT;
// Enable breathing interrupt
TIMSK1 |= _BV(OCIE1A);
}
void breathing_pulse(void)
{
if (get_backlight_level() == 0)
{
breathing_index = 0;
}
else
{
// Set breathing_index to be at the midpoint + 1 (brightest point)
breathing_index = 0x21 << breath_speed;
}
breathing_halt = BREATHING_HALT_ON;
// Enable breathing interrupt
TIMSK1 |= _BV(OCIE1A);
}
void breathing_disable(void)
{
// Disable breathing interrupt
TIMSK1 &= ~_BV(OCIE1A);
backlight_set(get_backlight_level());
}
void breathing_self_disable(void)
{
if (get_backlight_level() == 0)
{
breathing_halt = BREATHING_HALT_OFF;
}
else
{
breathing_halt = BREATHING_HALT_ON;
}
//backlight_set(get_backlight_level());
}
void breathing_toggle(void)
{
if (!is_breathing())
{
if (get_backlight_level() == 0)
{
breathing_index = 0;
}
else
{
// Set breathing_index to be at the midpoint + 1 (brightest point)
breathing_index = 0x21 << breath_speed;
}
breathing_halt = BREATHING_NO_HALT;
}
// Toggle breathing interrupt
TIMSK1 ^= _BV(OCIE1A);
// Restore backlight level
if (!is_breathing())
{
backlight_set(get_backlight_level());
}
}
bool is_breathing(void)
{
return (TIMSK1 && _BV(OCIE1A));
}
void breathing_intensity_default(void)
{
//breath_intensity = (uint8_t)((uint16_t)100 * (uint16_t)get_backlight_level() / (uint16_t)BACKLIGHT_LEVELS);
breath_intensity = ((BACKLIGHT_LEVELS - get_backlight_level()) * ((BACKLIGHT_LEVELS + 1) / 2));
}
void breathing_intensity_set(uint8_t value)
{
breath_intensity = value;
}
void breathing_speed_default(void)
{
breath_speed = 4;
}
void breathing_speed_set(uint8_t value)
{
bool is_breathing_now = is_breathing();
uint8_t old_breath_speed = breath_speed;
if (is_breathing_now)
{
// Disable breathing interrupt
TIMSK1 &= ~_BV(OCIE1A);
}
breath_speed = value;
if (is_breathing_now)
{
// Adjust index to account for new speed
breathing_index = (( (uint8_t)( (breathing_index) >> old_breath_speed ) ) & 0x3F) << breath_speed;
// Enable breathing interrupt
TIMSK1 |= _BV(OCIE1A);
}
}
void breathing_speed_inc(uint8_t value)
{
if ((uint16_t)(breath_speed - value) > 10 )
{
breathing_speed_set(0);
}
else
{
breathing_speed_set(breath_speed - value);
}
}
void breathing_speed_dec(uint8_t value)
{
if ((uint16_t)(breath_speed + value) > 10 )
{
breathing_speed_set(10);
}
else
{
breathing_speed_set(breath_speed + value);
}
}
void breathing_defaults(void)
{
breathing_intensity_default();
breathing_speed_default();
breathing_halt = BREATHING_NO_HALT;
}
/* Breathing Sleep LED brighness(PWM On period) table
* (64[steps] * 4[duration]) / 64[PWM periods/s] = 4 second breath cycle
*
* http://www.wolframalpha.com/input/?i=%28sin%28+x%2F64*pi%29**8+*+255%2C+x%3D0+to+63
* (0..63).each {|x| p ((sin(x/64.0*PI)**8)*255).to_i }
*/
static const uint8_t breathing_table[64] PROGMEM = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 2, 4, 6, 10,
15, 23, 32, 44, 58, 74, 93, 113, 135, 157, 179, 199, 218, 233, 245, 252,
255, 252, 245, 233, 218, 199, 179, 157, 135, 113, 93, 74, 58, 44, 32, 23,
15, 10, 6, 4, 2, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
};
ISR(TIMER1_COMPA_vect)
{
// OCR1x = (pgm_read_byte(&breathing_table[ ( (uint8_t)( (breathing_index++) >> breath_speed ) ) & 0x3F ] )) * breath_intensity;
uint8_t local_index = ( (uint8_t)( (breathing_index++) >> breath_speed ) ) & 0x3F;
if (((breathing_halt == BREATHING_HALT_ON) && (local_index == 0x20)) || ((breathing_halt == BREATHING_HALT_OFF) && (local_index == 0x3F)))
{
// Disable breathing interrupt
TIMSK1 &= ~_BV(OCIE1A);
}
OCR1x = (uint16_t)(((uint16_t)pgm_read_byte(&breathing_table[local_index]) * 257)) >> breath_intensity;
}
#endif // breathing
#else // backlight
__attribute__ ((weak))
void backlight_init_ports(void)
{
}
__attribute__ ((weak))
void backlight_set(uint8_t level)
{
}
#endif // backlight
// Functions for spitting out values
//
void send_dword(uint32_t number) { // this might not actually work
uint16_t word = (number >> 16);
send_word(word);
send_word(number & 0xFFFFUL);
}
void send_word(uint16_t number) {
uint8_t byte = number >> 8;
send_byte(byte);
send_byte(number & 0xFF);
}
void send_byte(uint8_t number) {
uint8_t nibble = number >> 4;
send_nibble(nibble);
send_nibble(number & 0xF);
}
void send_nibble(uint8_t number) {
switch (number) {
case 0:
register_code(KC_0);
unregister_code(KC_0);
break;
case 1 ... 9:
register_code(KC_1 + (number - 1));
unregister_code(KC_1 + (number - 1));
break;
case 0xA ... 0xF:
register_code(KC_A + (number - 0xA));
unregister_code(KC_A + (number - 0xA));
break;
}
}
__attribute__((weak))
uint16_t hex_to_keycode(uint8_t hex)
{
if (hex == 0x0) {
return KC_0;
} else if (hex < 0xA) {
return KC_1 + (hex - 0x1);
} else {
return KC_A + (hex - 0xA);
}
}
void api_send_unicode(uint32_t unicode) {
#ifdef API_ENABLE
uint8_t chunk[4];
dword_to_bytes(unicode, chunk);
MT_SEND_DATA(DT_UNICODE, chunk, 5);
#endif
}
__attribute__ ((weak))
void led_set_user(uint8_t usb_led) {
}
__attribute__ ((weak))
void led_set_kb(uint8_t usb_led) {
led_set_user(usb_led);
}
__attribute__ ((weak))
void led_init_ports(void)
{
}
__attribute__ ((weak))
void led_set(uint8_t usb_led)
{
// Example LED Code
//
// // Using PE6 Caps Lock LED
// if (usb_led & (1<<USB_LED_CAPS_LOCK))
// {
// // Output high.
// DDRE |= (1<<6);
// PORTE |= (1<<6);
// }
// else
// {
// // Output low.
// DDRE &= ~(1<<6);
// PORTE &= ~(1<<6);
// }
led_set_kb(usb_led);
}
//------------------------------------------------------------------------------
// Override these functions in your keymap file to play different tunes on
// different events such as startup and bootloader jump
__attribute__ ((weak))
void startup_user() {}
__attribute__ ((weak))
void shutdown_user() {}
//------------------------------------------------------------------------------