qmk_firmware/keyboards/chromatonemini/keymaps/party/keymap.c

700 lines
27 KiB
C

/* Copyright 2021 3araht
*
* 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 QMK_KEYBOARD_H
#include "version.h"
// define which MIDI ch to use.
// Note that (actual MIDI ch# - 1) -> 0 .. 15 is used for coding.
// ch1
#define DEFAULT_MAIN_CH_NUMBER 0
// ch3
#define DEFAULT_SUB_CH_NUMBER 2
// ch2
#define ALT_MAIN_CH_NUMBER 1
// ch4
#define ALT_SUB_CH_NUMBER 3
static uint8_t midi_left_ch = DEFAULT_SUB_CH_NUMBER; // By default, DEFAULT_SUB_CH_NUMBER is used for left side when separated.
// By default( when use_alt_ch_gr == false), DEFAULT ch group (DEFAULT_MAIN_CH_NUMBER for entirely, or right side when separated, DEFAULT_SUB_CH_NUMBER for left side) is used.
// When false, ALT ch group (ALT_MAIN_CH_NUMBER for entirely, or right side when separated, ALT_SUB_CH_NUMBER for left side) is used.
static bool use_alt_ch_gr = false;
// Defines names for use in layer keycodes and the keymap
enum layer_names {
_BASE, // Base layer, shift mode, single channel.
_SEPALEFTOCT, // 1st oct channel separated version. Shift mode.
_SEPAHALF, // Half channel separated version. Shift mode.
_SEPARIGHTOCT, // 2nd oct channel separated version. Shift mode.
_TRANS, // Transpose feature is enabled instead of shift mode, single channel.
_FLIPBASE, // Horizontal flipped version entirely. single channel.
_FLIPTRANS, // Horizontal flipped version entirely. Transpose is used. single channel.
_FN // FuNction layer. This must be at the end of the enumurate to use the range from _LS_FN ... _LS_FN_MAX for FN layer LED settings.
};
// Layer State
#define _LS_BASE (1UL << _BASE)
#define _LS_SEPALEFTOCT (1UL << _SEPALEFTOCT)
#define _LS_SEPAHALF (1UL << _SEPAHALF)
#define _LS_SEPARIGHTOCT (1UL << _SEPARIGHTOCT)
#define _LS_FLIPBASE (1UL << _FLIPBASE)
#define _LS_TRANS (1UL << _BASE | 1UL << _TRANS)
#define _LS_SEPALEFTOCT_T (1UL << _SEPALEFTOCT | 1UL << _TRANS)
#define _LS_SEPAHALF_T (1UL << _SEPAHALF | 1UL << _TRANS)
#define _LS_SEPARIGHTOCT_T (1UL << _SEPARIGHTOCT | 1UL << _TRANS)
#define _LS_FLIPTRANS (1UL << _FLIPBASE | 1UL << _FLIPTRANS)
#define _LS_FN (1UL << _FN)
#define _LS_MAX (_LS_FN << 1)
// Don't change the DEFAULT_SCALE_COL value below. It must be 0.
#define DEFAULT_SCALE_COL 0
static uint8_t scale_indicator_col = DEFAULT_SCALE_COL;
static bool trans_mode_indicator_loc_sel = true; // when it is true, the location is _KEY01, _KEY13, ...
// use led indicator or not.
static bool led_indicator_enable = true;
// Defines the keycodes used by our macros in process_record_user
enum custom_keycodes {
SHIFT_L = SAFE_RANGE,
SHIFT_R,
TGLINDI, // ToGgLe INDIcator
TGLINTR, // ToGgLe INdicator location {(_KEY01, _KEY13, _KEY25, _KEY37) or (_KEY02, _KEY14, _KEY26) / (_KEY12, _KEY24, _KEY36)}in TRans mode
TGLTRNS, // ToGgLe TRaNS and shift
TGLCHGR, // ToGgLe CH GRoup
VERSION,
B_BASE, // border set to the left end.
B_LEFT, // border set to the 1st left octave.
B_CENTER, // border set to the center.
B_RIGHT, // border set to the 1st right octave.
B_FLIP, // border set to the right end.
// MY tone for _FLIPHALF and _FLIPLEFTOCT layers to distinguish the notes to avoid sustain effect, etc.
// Since they are flipped, their subscripts are not MY_ but YM_, to make them easier to tell.
YM_TONE_MIN,
YM_C = YM_TONE_MIN,
YM_Cs,
YM_Db = YM_Cs,
YM_D,
YM_Ds,
YM_Eb = YM_Ds,
YM_E,
YM_F,
YM_Fs,
YM_Gb = YM_Fs,
YM_G,
YM_Gs,
YM_Ab = YM_Gs,
YM_A,
YM_As,
YM_Bb = YM_As,
YM_B,
YM_C_1,
YM_Cs_1,
YM_Db_1 = YM_Cs_1,
YM_D_1,
YM_Ds_1,
YM_Eb_1 = YM_Ds_1,
YM_E_1,
YM_F_1,
YM_Fs_1,
YM_Gb_1 = YM_Fs_1,
YM_G_1,
YM_Gs_1,
YM_Ab_1 = YM_Gs_1,
YM_A_1,
YM_As_1,
YM_Bb_1 = YM_As_1,
YM_B_1,
YM_C_2,
YM_Cs_2,
YM_Db_2 = YM_Cs_2,
YM_D_2,
YM_Ds_2,
YM_Eb_2 = YM_Ds_2,
YM_E_2,
YM_F_2,
YM_Fs_2,
YM_Gb_2 = YM_Fs_2,
YM_G_2,
YM_Gs_2,
YM_Ab_2 = YM_Gs_2,
YM_A_2,
YM_As_2,
YM_Bb_2 = YM_As_2,
YM_B_2,
YM_C_3,
YM_Cs_3,
YM_Db_3 = YM_Cs_3,
YM_D_3,
YM_Ds_3,
YM_Eb_3 = YM_Ds_3,
YM_E_3,
YM_F_3,
YM_Fs_3,
YM_Gb_3 = YM_Fs_3,
YM_G_3,
YM_Gs_3,
YM_Ab_3 = YM_Gs_3,
YM_A_3,
YM_As_3,
YM_Bb_3 = YM_As_3,
YM_B_3,
YM_C_4,
YM_Cs_4,
YM_Db_4 = YM_Cs_4,
YM_D_4,
YM_Ds_4,
YM_Eb_4 = YM_Ds_4,
YM_E_4,
YM_F_4,
YM_Fs_4,
YM_Gb_4 = YM_Fs_4,
YM_G_4,
YM_Gs_4,
YM_Ab_4 = YM_Gs_4,
YM_A_4,
YM_As_4,
YM_Bb_4 = YM_As_4,
YM_B_4,
YM_C_5,
YM_Cs_5,
YM_Db_5 = YM_Cs_5,
YM_D_5,
YM_Ds_5,
YM_Eb_5 = YM_Ds_5,
YM_E_5,
YM_F_5,
YM_Fs_5,
YM_Gb_5 = YM_Fs_5,
YM_G_5,
YM_Gs_5,
YM_Ab_5 = YM_Gs_5,
YM_A_5,
YM_As_5,
YM_Bb_5 = YM_As_5,
YM_B_5,
YM_C_6,
YM_TONE_MAX = YM_C_6
};
#define MY_TONE_COUNT (YM_TONE_MAX - YM_TONE_MIN + 1)
static uint8_t my_tone_status[MY_TONE_COUNT];
// Long press: go to _FN layer, tap: MUTE
#define FN_MUTE LT(_FN, KC_MUTE)
// Used to set octave to MI_OCT_0
extern midi_config_t midi_config;
static bool is_trans_mode = false; // By default, shift mode is chosen.
static uint8_t key_separator_col = _KEY01; // (_KEY01 .. _KEY37). By default, _KEY01 (= _BASE layer) is chosen. _KEY13 = *LEFT, _KEY19 = *HALF, _KEY25 = *RIGHT, _KEY37 = _FLIPBASE and _FLIPTRANS.
const uint16_t PROGMEM keymaps[][MATRIX_ROWS][MATRIX_COLS] = {
/* Base */
[_BASE] = LAYOUT(
FN_MUTE, MI_SUS,
MI_BENDU,
SHIFT_L, SHIFT_R, MI_C_2, MI_D_2, MI_E_2, MI_Fs_2, MI_Ab_2, MI_Bb_2, MI_C_3, MI_D_3, MI_E_3, MI_Fs_3, MI_Ab_3, MI_Bb_3, MI_C_4, MI_D_4, MI_E_4, MI_Fs_4, MI_Ab_4, MI_Bb_4, MI_C_5,
MI_BENDD, MI_Db_2, MI_Eb_2, MI_F_2, MI_G_2, MI_A_2, MI_B_2, MI_Db_3, MI_Eb_3, MI_F_3, MI_G_3, MI_A_3, MI_B_3, MI_Db_4, MI_Eb_4, MI_F_4, MI_G_4, MI_A_4, MI_B_4
),
/* 1 octave on the left side is ch2, others are ch1 (normal) */
[_SEPALEFTOCT] = LAYOUT(
_______, _______,
_______,
SHIFT_L, SHIFT_R, YM_C_2, YM_D_2, YM_E_2, YM_Fs_2, YM_Ab_2, YM_Bb_2, MI_C_3, MI_D_3, MI_E_3, MI_Fs_3, MI_Ab_3, MI_Bb_3, MI_C_4, MI_D_4, MI_E_4, MI_Fs_4, MI_Ab_4, MI_Bb_4, MI_C_5,
_______, YM_Db_2, YM_Eb_2, YM_F_2, YM_G_2, YM_A_2, YM_B_2, MI_Db_3, MI_Eb_3, MI_F_3, MI_G_3, MI_A_3, MI_B_3, MI_Db_4, MI_Eb_4, MI_F_4, MI_G_4, MI_A_4, MI_B_4
),
/* Half ch2, half ch1 (normal) */
[_SEPAHALF] = LAYOUT(
_______, _______,
_______,
SHIFT_L, SHIFT_R, YM_C_2, YM_D_2, YM_E_2, YM_Fs_2, YM_Ab_2, YM_Bb_2, YM_C_3, YM_D_3, YM_E_3, MI_Fs_3, MI_Ab_3, MI_Bb_3, MI_C_4, MI_D_4, MI_E_4, MI_Fs_4, MI_Ab_4, MI_Bb_4, MI_C_5,
_______, YM_Db_2, YM_Eb_2, YM_F_2, YM_G_2, YM_A_2, YM_B_2, YM_Db_3, YM_Eb_3, YM_F_3, MI_G_3, MI_A_3, MI_B_3, MI_Db_4, MI_Eb_4, MI_F_4, MI_G_4, MI_A_4, MI_B_4
),
/* 2 octave on the left side is ch2, others are ch1 (normal) */
[_SEPARIGHTOCT] = LAYOUT(
_______, _______,
_______,
SHIFT_L, SHIFT_R, YM_C_2, YM_D_2, YM_E_2, YM_Fs_2, YM_Ab_2, YM_Bb_2, YM_C_3, YM_D_3, YM_E_3, YM_Fs_3, YM_Ab_3, YM_Bb_3, MI_C_4, MI_D_4, MI_E_4, MI_Fs_4, MI_Ab_4, MI_Bb_4, MI_C_5,
_______, YM_Db_2, YM_Eb_2, YM_F_2, YM_G_2, YM_A_2, YM_B_2, YM_Db_3, YM_Eb_3, YM_F_3, YM_G_3, YM_A_3, YM_B_3, MI_Db_4, MI_Eb_4, MI_F_4, MI_G_4, MI_A_4, MI_B_4
),
/* TRANS This layer must locate 1 layer below _FN layer. */
[_TRANS] = LAYOUT(
_______, _______,
_______,
MI_TRNSD, MI_TRNSU, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______,
_______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______
),
/* Flip Base SFIFTUP and SHIFT_L are swapped. */
[_FLIPBASE] = LAYOUT(
FN_MUTE, MI_SUS,
MI_BENDU,
SHIFT_L, SHIFT_R, MI_C_5, MI_Bb_4, MI_Ab_4, MI_Fs_4, MI_E_4, MI_D_4, MI_C_4, MI_Bb_3, MI_Ab_3, MI_Fs_3, MI_E_3, MI_D_3, MI_C_3, MI_Bb_2, MI_Ab_2, MI_Fs_2, MI_E_2, MI_D_2, MI_C_2,
MI_BENDD, MI_B_4, MI_A_4, MI_G_4, MI_F_4, MI_Eb_4, MI_Db_4, MI_B_3, MI_A_3, MI_G_3, MI_F_3, MI_Eb_3, MI_Db_3, MI_B_2, MI_A_2, MI_G_2, MI_F_2, MI_Eb_2, MI_Db_2
),
/* Flip Trans This layer must locate 1 layer above _FLIPBASE layer. MI_TRNSU and MI_TRNSD are swapped. */
[_FLIPTRANS] = LAYOUT(
_______, _______,
_______,
MI_TRNSU, MI_TRNSD, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______,
_______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______, _______
),
[_FN] = LAYOUT(
_______, XXXXXXX,
MI_VELU,
MI_OCTD, MI_OCTU, B_BASE, XXXXXXX, XXXXXXX, XXXXXXX, XXXXXXX, XXXXXXX, B_LEFT, XXXXXXX, XXXXXXX, B_CENTER, XXXXXXX, XXXXXXX, B_RIGHT, XXXXXXX, XXXXXXX, XXXXXXX, VERSION, XXXXXXX, B_FLIP,
MI_VELD, TGLINTR, TGLTRNS, TGLCHGR, XXXXXXX, XXXXXXX, RGB_SAD, RGB_SAI, RGB_HUD, RGB_HUI, RGB_SPD, RGB_SPI, RGB_VAD, RGB_VAI, RGB_RMOD, RGB_MOD, EE_CLR, TGLINDI, RGB_TOG
)
};
#if defined(ENCODER_MAP_ENABLE)
const uint16_t PROGMEM encoder_map[][NUM_ENCODERS][2] = {
[_BASE] = { ENCODER_CCW_CW(KC_VOLD, KC_VOLU) },
[_SEPALEFTOCT] = { ENCODER_CCW_CW(_______, _______) },
[_SEPAHALF] = { ENCODER_CCW_CW(_______, _______) },
[_SEPARIGHTOCT] = { ENCODER_CCW_CW(_______, _______) },
[_TRANS] = { ENCODER_CCW_CW(_______, _______) },
[_FLIPBASE] = { ENCODER_CCW_CW(KC_VOLD, KC_VOLU) },
[_FLIPTRANS] = { ENCODER_CCW_CW(_______, _______) },
[_FN] = { ENCODER_CCW_CW(RGB_RMOD, RGB_MOD) },
};
#endif
// commom codes called from eeconfig_init_user() and keyboard_post_init_user().
void my_init(void){
// Set octave to MI_OCT_1
midi_config.octave = MI_OCT_0 - MIDI_OCTAVE_MIN;
// avoid using 127 since it is used as a special number in some sound sources.
midi_config.velocity = MIDI_INITIAL_VELOCITY;
default_layer_set(_LS_BASE);
layer_state_set(_LS_BASE);
#ifdef RGB_MATRIX_ENABLE
rgb_matrix_sethsv(HSV_BLUE);
// party mode (for LED soldering test. Enable rainbow color effect, and disable led_indicator to check all LEDs)
rgb_matrix_mode(RGB_MATRIX_RAINBOW_MOVING_CHEVRON);
led_indicator_enable = false;
#endif // RGB_MATRIX_ENABLE
}
void eeconfig_init_user(void) { // EEPROM is getting reset!
midi_init();
#ifdef RGB_MATRIX_ENABLE
rgb_matrix_enable();
rgb_matrix_set_speed(RGB_MATRIX_STARTUP_SPD);
#endif // RGB_MATRIX_ENABLE
my_init(); // commom codes called from eeconfig_init_user() and keyboard_post_init_user().
}
void keyboard_post_init_user(void) {
for (uint8_t i = 0; i < MY_TONE_COUNT; i++) {
my_tone_status[i] = MIDI_INVALID_NOTE;
}
my_init(); // commom codes called from eeconfig_init_user() and keyboard_post_init_user().
}
void reset_scale_indicator(void) {
// reset transpose value and scale_indicator_col to default.
midi_config.transpose = 0;
scale_indicator_col = DEFAULT_SCALE_COL;
trans_mode_indicator_loc_sel = true;
}
void reset_all(void) {
reset_scale_indicator();
is_trans_mode = false; // trans mode is disabled by default.
}
void my_process_midi4single_note(uint8_t channel, uint16_t keycode, keyrecord_t *record, uint8_t *my_tone_status) {
uint8_t mytone = keycode - YM_TONE_MIN;
uint16_t mykeycode = mytone + MIDI_TONE_MIN;
// uint16_t mykeycode = keycode - YM_TONE_MIN;
// uint8_t mytone = mykeycode - MIDI_TONE_MIN;
uint8_t velocity = midi_config.velocity;
// uprintf("keycode=%u,mykeycode=%u,mytone =%u,velo = %u\n", keycode, mykeycode, mytone, velocity);
if (record->event.pressed) {
if (my_tone_status[mytone] == MIDI_INVALID_NOTE) {
uint8_t note = midi_compute_note(mykeycode);
midi_send_noteon(&midi_device, channel, note, velocity);
dprintf("midi noteon channel:%d note:%d mytone:%d velocity:%d\n", channel, note, mytone, velocity);
// uprintf("midi noteon channel:%d note:%d mytone:%d velocity:%d\n", channel, note, mytone, velocity);
my_tone_status[mytone] = note; // store root_note status.
}
} else {
uint8_t note = my_tone_status[mytone];
if (note != MIDI_INVALID_NOTE) {
midi_send_noteoff(&midi_device, channel, note, velocity);
dprintf("midi noteoff channel:%d note:%d velocity:%d\n", channel, note, velocity);
// uprintf("midi noteoff channel:%d note:%d velocity:%d\n", channel, note, velocity);
}
my_tone_status[mytone] = MIDI_INVALID_NOTE;
}
}
void select_layer_state_set(void) {
switch (key_separator_col) {
case _KEY01:
if (is_trans_mode) {
layer_state_set(_LS_TRANS);
} else {
layer_state_set(_LS_BASE);
}
break;
case _KEY13:
if (is_trans_mode) {
layer_state_set(_LS_SEPALEFTOCT_T);
} else {
layer_state_set(_LS_SEPALEFTOCT);
}
break;
case _KEY19:
if (is_trans_mode) {
layer_state_set(_LS_SEPAHALF_T);
} else {
layer_state_set(_LS_SEPAHALF);
}
break;
case _KEY25:
if (is_trans_mode) {
layer_state_set(_LS_SEPARIGHTOCT_T);
} else {
layer_state_set(_LS_SEPARIGHTOCT);
}
break;
case _KEY37:
if (is_trans_mode) {
layer_state_set(_LS_FLIPTRANS);
} else {
layer_state_set(_LS_FLIPBASE);
}
break;
}
}
bool process_record_user(uint16_t keycode, keyrecord_t *record) {
// uprintf("keycode=%u, YM_C_3=%u, YM_Db_2 =%u, YM_MIN = %u, YM_MAX = %u\n", keycode, YM_C_3, YM_Db_2, YM_TONE_MIN, YM_TONE_MAX);
switch (keycode) {
case VERSION: // Output firmware info.
if (record->event.pressed) {
SEND_STRING(QMK_KEYBOARD ":" QMK_KEYMAP " @ " QMK_VERSION " | " QMK_BUILDDATE);
}
break;
// Layer-related settings.
// reset_scale_indicator() first, followed by each modification, and then change the default layer.
// 1, separator column modification
case B_BASE:
if (record->event.pressed) {
reset_all();
key_separator_col = _KEY01;
select_layer_state_set();
}
break;
case B_LEFT:
if (record->event.pressed) {
reset_all();
key_separator_col = _KEY13;
select_layer_state_set();
}
break;
case B_CENTER:
if (record->event.pressed) {
reset_all();
key_separator_col = _KEY19;
select_layer_state_set();
}
break;
case B_RIGHT:
if (record->event.pressed) {
reset_all();
key_separator_col = _KEY25;
select_layer_state_set();
}
break;
case B_FLIP:
if (record->event.pressed) {
reset_all();
key_separator_col = _KEY37;
select_layer_state_set();
}
break;
// 2, Toggle scale shift mode and transpose mode
case TGLTRNS:
if (record->event.pressed) {
reset_scale_indicator();
is_trans_mode = !is_trans_mode;
select_layer_state_set();
}
break;
// SHIFT_L and SHIFT_R can be pressed only when layer is either _BASE, _FLIPBASE.
case SHIFT_L:
if (record->event.pressed) {
switch (layer_state) {
case _LS_BASE:
case _LS_SEPALEFTOCT:
case _LS_SEPAHALF:
case _LS_SEPARIGHTOCT:
case _LS_FLIPBASE:
scale_indicator_col = shift_led_indicator_left(scale_indicator_col);
break;
}
}
break;
case SHIFT_R:
if (record->event.pressed) {
switch (layer_state) {
case _LS_BASE:
case _LS_SEPALEFTOCT:
case _LS_SEPAHALF:
case _LS_SEPARIGHTOCT:
case _LS_FLIPBASE:
scale_indicator_col = shift_led_indicator_right(scale_indicator_col);
break;
}
}
break;
case TGLINDI:
if (record->event.pressed) {
led_indicator_enable = !led_indicator_enable;
}
break;
case TGLINTR:
if (record->event.pressed) {
switch (layer_state) {
// main function of the TGLINTR part 1. alternate the status of trans_mode_indicator_loc_sel.
case _LS_TRANS | (1UL << _FN):
case _LS_SEPALEFTOCT_T | (1UL << _FN):
case _LS_SEPAHALF_T | (1UL << _FN):
case _LS_SEPARIGHTOCT_T | (1UL << _FN):
trans_mode_indicator_loc_sel = !trans_mode_indicator_loc_sel;
// when trans_mode_indicator_loc_sel == false, change the scale indicator and transpose.
scale_indicator_col = trans_mode_indicator_loc_sel ? 0:1;
// when TGLINTR is pressed, it also change the initial transpose setting to follow the scale indicator.
if (scale_indicator_col == 1) {
midi_config.transpose = -1;
} else {
midi_config.transpose = 0;
}
break;
// main function of the TGLINTR part 2. alternate the status of trans_mode_indicator_loc_sel.
case _LS_FLIPTRANS | (1UL << _FN):
trans_mode_indicator_loc_sel = !trans_mode_indicator_loc_sel;
// when trans_mode_indicator_loc_sel == false, change the scale indicator and transpose.
scale_indicator_col = trans_mode_indicator_loc_sel ? 0:11;
// when TGLINTR is pressed, it also change the initial transpose setting to follow the scale indicator.
if (scale_indicator_col == 11) {
midi_config.transpose = -1;
} else {
midi_config.transpose = 0;
}
break;
// special treatment when TGLINTR is pressed in _LS_FLIPBASE layer.
case _LS_FLIPBASE | (1UL << _FN): // when in FLIPBASE layer && non-Trans mode, change it to Trans mode.
trans_mode_indicator_loc_sel = false;
scale_indicator_col = 11;
midi_config.transpose = -1;
is_trans_mode = true;
select_layer_state_set();
break;
// special treatment when TGLINTR is pressed in other non-Trans layer.
default : // when other layers = non-Trans mode, change it to Trans mode.
trans_mode_indicator_loc_sel = false;
scale_indicator_col = 1;
midi_config.transpose = -1;
is_trans_mode = true;
select_layer_state_set();
}
}
break;
case TGLCHGR:
if (record->event.pressed) {
use_alt_ch_gr = !use_alt_ch_gr;
if (use_alt_ch_gr) {
midi_config.channel = ALT_MAIN_CH_NUMBER;
midi_left_ch = ALT_SUB_CH_NUMBER;
} else { // default
midi_config.channel = DEFAULT_MAIN_CH_NUMBER;
midi_left_ch = DEFAULT_SUB_CH_NUMBER;
}
}
break;
case YM_TONE_MIN ... YM_TONE_MAX: // MY tone
// uprintf("keycode=%u, YM_C_3=%u, YM_Db_2 =%u, YM_MIN = %u, YM_MAX = %u\n", keycode, YM_C_3, YM_Db_2, YM_TONE_MIN, YM_TONE_MAX);
// DO NOT THROW BELOW into 'if (record->event.pressed) {}' STATEMENT SINCE IT IS USED IN THE FUNCTION BELOW.
my_process_midi4single_note(midi_left_ch, keycode, record, my_tone_status);
break;
}
return true;
}
#ifdef RGB_MATRIX_ENABLE
void set_led_scale_indicator(uint8_t r, uint8_t g, uint8_t b) {
uint8_t max_scale_indicator_led_loop;
uint8_t i;
if (led_indicator_enable) { // turn on indicators when enabled.
max_scale_indicator_led_loop = ( scale_indicator_col == DEFAULT_SCALE_COL ) ? 12 : 9;
for (i = 0; i < max_scale_indicator_led_loop; i++) {
rgb_matrix_set_color(led_scale_indicator[scale_indicator_col][i], r, g, b);
}
}
}
bool rgb_matrix_indicators_user(void) {
// uint32_t mode = rgblight_get_mode();
if (rgb_matrix_is_enabled()) { // turn the lights on when it is enabled.
// uint8_t max_scale_indicator_led_loop;
uint8_t i;
switch (layer_state) {
case _LS_BASE:
set_led_scale_indicator(BASE_LAYER_COLOR);
break;
case _LS_FLIPBASE:
set_led_scale_indicator(FLIPB_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY37][i], FLIP_BORDER_COLOR); // right end
}
break;
case _LS_TRANS:
set_led_scale_indicator(TRANS_LAYER_COLOR);
break;
case _LS_SEPALEFTOCT_T:
set_led_scale_indicator(SEPALEFT_T_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY13][i], FLIP_BORDER_COLOR); // Left
}
break;
case _LS_SEPAHALF_T:
set_led_scale_indicator(SEPAHALF_T_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY19][i], FLIP_BORDER_COLOR); // Center
}
break;
case _LS_SEPARIGHTOCT_T:
set_led_scale_indicator(SEPARIGHT_T_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY25][i], FLIP_BORDER_COLOR); // Right
}
break;
case _LS_FLIPTRANS:
set_led_scale_indicator(FLIPT_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY37][i], FLIP_BORDER_COLOR); // right end
}
break;
case _LS_SEPALEFTOCT:
set_led_scale_indicator(SEPALEFT_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY13][i], FLIP_BORDER_COLOR); // Left
}
break;
case _LS_SEPAHALF:
set_led_scale_indicator(SEPAHALF_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY19][i], FLIP_BORDER_COLOR); // Center
}
break;
case _LS_SEPARIGHTOCT:
set_led_scale_indicator(SEPARIGHT_LAYER_COLOR);
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY25][i], FLIP_BORDER_COLOR); // Right
}
break;
case _LS_FN ... _LS_MAX: // When Mute Button is long-pressed, the previous layers are still active.
for (i = 1; i < 5; i++) {
rgb_matrix_set_color(i, RGB_DARKSPRINGGREEN); // up(1) down(4) left(3) right(2) keys
}
rgb_matrix_set_color(led_single_col_indicator[_KEY02][0], RGB_DARKSPRINGGREEN); // TGLTRNS
rgb_matrix_set_color(led_single_col_indicator[_KEY04][0], RGB_DARKSPRINGGREEN); // TGLINTR
rgb_matrix_set_color(led_single_col_indicator[_KEY06][0], RGB_DARKSPRINGGREEN); // TGLCHGR
for (i = 0; i < 3; i++) {
rgb_matrix_set_color(led_single_col_indicator[_KEY01][i], BASE_LAYER_COLOR); // B_BASE
rgb_matrix_set_color(led_single_col_indicator[_KEY13][i], SEPALEFT_LAYER_COLOR); // B_LEFT
rgb_matrix_set_color(led_single_col_indicator[_KEY19][i], SEPAHALF_LAYER_COLOR); // B_CENTER
rgb_matrix_set_color(led_single_col_indicator[_KEY25][i], SEPARIGHT_LAYER_COLOR); // B_RIGHT
rgb_matrix_set_color(led_single_col_indicator[_KEY37][i], FLIPB_LAYER_COLOR); // B_FLIP
}
for (i = _KEY12; i < _KEY37; i+=2){ // even numbers from _KEY12 to _KEY36 are LED related settings.
// turn on the bottom row only to keep the visibility of the RGB MATRIX effects.
rgb_matrix_set_color(led_single_col_indicator[i][0], RGB_DARKSPRINGGREEN); // // LED related settings.
}
break;
}
}
return false;
}
#endif // RGB_MATRIX_ENABLE