qmk/ferris/achordion.c

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2023-06-11 11:43:07 +02:00
// Copyright 2022-2023 Google LLC
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/**
* @file achordion.c
* @brief Achordion implementation
*
* For full documentation, see
* <https://getreuer.info/posts/keyboards/achordion>
*/
#include "achordion.h"
// Copy of the `record` and `keycode` args for the current active tap-hold key.
static keyrecord_t tap_hold_record;
static uint16_t tap_hold_keycode = KC_NO;
// Timeout timer. When it expires, the key is considered held.
static uint16_t hold_timer = 0;
// Eagerly applied mods, if any.
static uint8_t eager_mods = 0;
// Achordion's current state.
enum {
// A tap-hold key is pressed, but hasn't yet been settled as tapped or held.
STATE_UNSETTLED,
// Achordion is inactive.
STATE_RELEASED,
// Active tap-hold key has been settled as tapped.
STATE_TAPPING,
// Active tap-hold key has been settled as held.
STATE_HOLDING,
// This state is set while calling `process_record()`, which will recursively
// call `process_achordion()`. This state is checked so that we don't process
// events generated by Achordion and potentially create an infinite loop.
STATE_RECURSING,
};
static uint8_t achordion_state = STATE_RELEASED;
// Calls `process_record()` with state set to RECURSING.
static void recursively_process_record(keyrecord_t* record, uint8_t state) {
achordion_state = STATE_RECURSING;
process_record(record);
achordion_state = state;
}
// Clears eagerly-applied mods.
static void clear_eager_mods(void) {
unregister_mods(eager_mods);
eager_mods = 0;
}
// Sends hold press event and settles the active tap-hold key as held.
static void settle_as_hold(void) {
clear_eager_mods();
// Create hold press event.
recursively_process_record(&tap_hold_record, STATE_HOLDING);
}
bool process_achordion(uint16_t keycode, keyrecord_t* record) {
// Don't process events that Achordion generated.
if (achordion_state == STATE_RECURSING) {
return true;
}
// Determine whether the current event is for a mod-tap or layer-tap key.
const bool is_mt = IS_QK_MOD_TAP(keycode);
const bool is_tap_hold = is_mt || IS_QK_LAYER_TAP(keycode);
// Check that this is a normal key event, don't act on combos.
#ifdef IS_KEYEVENT
const bool is_key_event = IS_KEYEVENT(record->event);
#else
const bool is_key_event = (record->event.key.row < 254 &&
record->event.key.col < 254);
#endif
if (achordion_state == STATE_RELEASED) {
if (is_tap_hold && record->tap.count == 0 && record->event.pressed &&
is_key_event) {
// A tap-hold key is pressed and considered by QMK as "held".
const uint16_t timeout = achordion_timeout(keycode);
if (timeout > 0) {
achordion_state = STATE_UNSETTLED;
// Save info about this key.
tap_hold_keycode = keycode;
tap_hold_record = *record;
hold_timer = record->event.time + timeout;
if (is_mt) { // Apply mods immediately if they are "eager."
uint8_t mod = mod_config(QK_MOD_TAP_GET_MODS(tap_hold_keycode));
if (achordion_eager_mod(mod)) {
eager_mods = ((mod & 0x10) == 0) ? mod : (mod << 4);
register_mods(eager_mods);
}
}
dprintf("Achordion: Key 0x%04X pressed.%s\n", keycode,
eager_mods ? " Set eager mods." : "");
return false; // Skip default handling.
}
}
return true; // Otherwise, continue with default handling.
}
if (keycode == tap_hold_keycode && !record->event.pressed) {
// The active tap-hold key is being released.
if (achordion_state == STATE_HOLDING) {
dprintln("Achordion: Key released. Plumbing hold release.");
tap_hold_record.event.pressed = false;
// Plumb hold release event.
recursively_process_record(&tap_hold_record, STATE_RELEASED);
} else {
dprintf("Achordion: Key released.%s\n",
eager_mods ? " Clearing eager mods." : "");
if (is_mt) {
clear_eager_mods();
}
}
achordion_state = STATE_RELEASED;
return false;
}
if (achordion_state == STATE_UNSETTLED && record->event.pressed) {
// Press event occurred on a key other than the active tap-hold key.
// If the other key is *also* a tap-hold key and considered by QMK to be
// held, then we settle the active key as held. This way, things like
// chording multiple home row modifiers will work, but let's our logic
// consider simply a single tap-hold key as "active" at a time.
//
// Otherwise, we call `achordion_chord()` to determine whether to settle the
// tap-hold key as tapped vs. held. We implement the tap or hold by plumbing
// events back into the handling pipeline so that QMK features and other
// user code can see them. This is done by calling `process_record()`, which
// in turn calls most handlers including `process_record_user()`.
if (!is_key_event || (is_tap_hold && record->tap.count == 0) ||
achordion_chord(tap_hold_keycode, &tap_hold_record, keycode, record)) {
dprintln("Achordion: Plumbing hold press.");
settle_as_hold();
} else {
clear_eager_mods(); // Clear in case eager mods were set.
dprintln("Achordion: Plumbing tap press.");
tap_hold_record.tap.count = 1; // Revise event as a tap.
tap_hold_record.tap.interrupted = true;
// Plumb tap press event.
recursively_process_record(&tap_hold_record, STATE_TAPPING);
send_keyboard_report();
#if TAP_CODE_DELAY > 0
wait_ms(TAP_CODE_DELAY);
#endif // TAP_CODE_DELAY > 0
dprintln("Achordion: Plumbing tap release.");
tap_hold_record.event.pressed = false;
// Plumb tap release event.
recursively_process_record(&tap_hold_record, STATE_TAPPING);
}
recursively_process_record(record, achordion_state); // Re-process event.
return false; // Block the original event.
}
return true;
}
void achordion_task(void) {
if (achordion_state == STATE_UNSETTLED &&
timer_expired(timer_read(), hold_timer)) {
dprintln("Achordion: Timeout. Plumbing hold press.");
settle_as_hold(); // Timeout expired, settle the key as held.
}
}
// Returns true if `pos` on the left hand of the keyboard, false if right.
static bool on_left_hand(keypos_t pos) {
#ifdef SPLIT_KEYBOARD
return pos.row < MATRIX_ROWS / 2;
#else
return (MATRIX_COLS > MATRIX_ROWS) ? pos.col < MATRIX_COLS / 2
: pos.row < MATRIX_ROWS / 2;
#endif
}
bool achordion_opposite_hands(const keyrecord_t* tap_hold_record,
const keyrecord_t* other_record) {
return on_left_hand(tap_hold_record->event.key) !=
on_left_hand(other_record->event.key);
}
// By default, use the BILATERAL_COMBINATIONS rule to consider the tap-hold key
// "held" only when it and the other key are on opposite hands.
__attribute__((weak)) bool achordion_chord(uint16_t tap_hold_keycode,
keyrecord_t* tap_hold_record,
uint16_t other_keycode,
keyrecord_t* other_record) {
return achordion_opposite_hands(tap_hold_record, other_record);
}
// By default, the timeout is 1000 ms for all keys.
__attribute__((weak)) uint16_t achordion_timeout(uint16_t tap_hold_keycode) {
return 1000;
}
// By default, Shift and Ctrl mods are eager, and Alt and GUI are not.
__attribute__((weak)) bool achordion_eager_mod(uint8_t mod) {
return (mod & (MOD_LALT | MOD_LGUI)) == 0;
}