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/*
* Copyright (c) 2020 The ZMK Contributors
*
* SPDX-License-Identifier: MIT
*/
#define DT_DRV_COMPAT zmk_behavior_sticky_key
#include <device.h>
#include <drivers/behavior.h>
#include <logging/log.h>
#include <zmk/behavior.h>
#include <zmk/matrix.h>
#include <zmk/endpoints.h>
#include <zmk/event_manager.h>
#include <zmk/events/position_state_changed.h>
#include <zmk/events/keycode_state_changed.h>
#include <zmk/events/modifiers_state_changed.h>
#include <zmk/hid.h>
LOG_MODULE_DECLARE(zmk, CONFIG_ZMK_LOG_LEVEL);
#if DT_HAS_COMPAT_STATUS_OKAY(DT_DRV_COMPAT)
#define ZMK_BHV_STICKY_KEY_MAX_HELD 10
#define ZMK_BHV_STICKY_KEY_POSITION_FREE ULONG_MAX
struct behavior_sticky_key_config {
uint32_t release_after_ms;
struct zmk_behavior_binding behavior;
};
struct active_sticky_key {
uint32_t position;
uint32_t param1;
uint32_t param2;
const struct behavior_sticky_key_config *config;
// timer data.
bool timer_started;
bool timer_cancelled;
int64_t release_at;
struct k_delayed_work release_timer;
// usage page and keycode for the key that is being modified by this sticky key
uint8_t modified_key_usage_page;
uint32_t modified_key_keycode;
};
struct active_sticky_key active_sticky_keys[ZMK_BHV_STICKY_KEY_MAX_HELD] = {};
static struct active_sticky_key *store_sticky_key(uint32_t position, uint32_t param1,
uint32_t param2,
const struct behavior_sticky_key_config *config) {
for (int i = 0; i < ZMK_BHV_STICKY_KEY_MAX_HELD; i++) {
struct active_sticky_key *const sticky_key = &active_sticky_keys[i];
if (sticky_key->position != ZMK_BHV_STICKY_KEY_POSITION_FREE ||
sticky_key->timer_cancelled) {
continue;
}
sticky_key->position = position;
sticky_key->param1 = param1;
sticky_key->param2 = param2;
sticky_key->config = config;
sticky_key->release_at = 0;
sticky_key->timer_cancelled = false;
sticky_key->timer_started = false;
sticky_key->modified_key_usage_page = 0;
sticky_key->modified_key_keycode = 0;
return sticky_key;
}
return NULL;
}
static void clear_sticky_key(struct active_sticky_key *sticky_key) {
sticky_key->position = ZMK_BHV_STICKY_KEY_POSITION_FREE;
}
static struct active_sticky_key *find_sticky_key(uint32_t position) {
for (int i = 0; i < ZMK_BHV_STICKY_KEY_MAX_HELD; i++) {
if (active_sticky_keys[i].position == position && !active_sticky_keys[i].timer_cancelled) {
return &active_sticky_keys[i];
}
}
return NULL;
}
static inline int press_sticky_key_behavior(struct active_sticky_key *sticky_key,
int64_t timestamp) {
struct zmk_behavior_binding binding = {
.behavior_dev = sticky_key->config->behavior.behavior_dev,
.param1 = sticky_key->param1,
.param2 = sticky_key->param2,
};
struct zmk_behavior_binding_event event = {
.position = sticky_key->position,
.timestamp = timestamp,
};
return behavior_keymap_binding_pressed(&binding, event);
}
static inline int release_sticky_key_behavior(struct active_sticky_key *sticky_key,
int64_t timestamp) {
struct zmk_behavior_binding binding = {
.behavior_dev = sticky_key->config->behavior.behavior_dev,
.param1 = sticky_key->param1,
.param2 = sticky_key->param2,
};
struct zmk_behavior_binding_event event = {
.position = sticky_key->position,
.timestamp = timestamp,
};
clear_sticky_key(sticky_key);
return behavior_keymap_binding_released(&binding, event);
}
static int stop_timer(struct active_sticky_key *sticky_key) {
int timer_cancel_result = k_delayed_work_cancel(&sticky_key->release_timer);
if (timer_cancel_result == -EINPROGRESS) {
// too late to cancel, we'll let the timer handler clear up.
sticky_key->timer_cancelled = true;
}
return timer_cancel_result;
}
static int on_sticky_key_binding_pressed(struct zmk_behavior_binding *binding,
struct zmk_behavior_binding_event event) {
const struct device *dev = device_get_binding(binding->behavior_dev);
const struct behavior_sticky_key_config *cfg = dev->config;
struct active_sticky_key *sticky_key;
sticky_key = find_sticky_key(event.position);
if (sticky_key != NULL) {
stop_timer(sticky_key);
release_sticky_key_behavior(sticky_key, event.timestamp);
}
sticky_key = store_sticky_key(event.position, binding->param1, binding->param2, cfg);
if (sticky_key == NULL) {
LOG_ERR("unable to store sticky key, did you press more than %d sticky_key?",
ZMK_BHV_STICKY_KEY_MAX_HELD);
return ZMK_BEHAVIOR_OPAQUE;
}
press_sticky_key_behavior(sticky_key, event.timestamp);
LOG_DBG("%d new sticky_key", event.position);
return ZMK_BEHAVIOR_OPAQUE;
}
static int on_sticky_key_binding_released(struct zmk_behavior_binding *binding,
struct zmk_behavior_binding_event event) {
struct active_sticky_key *sticky_key = find_sticky_key(event.position);
if (sticky_key == NULL) {
LOG_ERR("ACTIVE STICKY KEY CLEARED TOO EARLY");
return ZMK_BEHAVIOR_OPAQUE;
}
if (sticky_key->modified_key_usage_page != 0 && sticky_key->modified_key_keycode != 0) {
LOG_DBG("Another key was pressed while the sticky key was pressed. Act like a normal key.");
return release_sticky_key_behavior(sticky_key, event.timestamp);
}
// No other key was pressed. Start the timer.
sticky_key->timer_started = true;
sticky_key->release_at = event.timestamp + sticky_key->config->release_after_ms;
// adjust timer in case this behavior was queued by a hold-tap
int32_t ms_left = sticky_key->release_at - k_uptime_get();
if (ms_left > 0) {
k_delayed_work_submit(&sticky_key->release_timer, K_MSEC(ms_left));
}
return ZMK_BEHAVIOR_OPAQUE;
}
static const struct behavior_driver_api behavior_sticky_key_driver_api = {
.binding_pressed = on_sticky_key_binding_pressed,
.binding_released = on_sticky_key_binding_released,
};
static int sticky_key_keycode_state_changed_listener(const zmk_event_t *eh) {
struct zmk_keycode_state_changed *ev = as_zmk_keycode_state_changed(eh);
if (ev == NULL) {
return ZMK_EV_EVENT_BUBBLE;
}
for (int i = 0; i < ZMK_BHV_STICKY_KEY_MAX_HELD; i++) {
struct active_sticky_key *sticky_key = &active_sticky_keys[i];
if (sticky_key->position == ZMK_BHV_STICKY_KEY_POSITION_FREE) {
continue;
}
if (strcmp(sticky_key->config->behavior.behavior_dev, "KEY_PRESS") == 0 &&
HID_USAGE_ID(sticky_key->param1) == ev->keycode &&
(HID_USAGE_PAGE(sticky_key->param1) & 0xFF) == ev->usage_page &&
SELECT_MODS(sticky_key->param1) == ev->implicit_modifiers) {
// don't catch key down events generated by the sticky key behavior itself
continue;
}
// If events were queued, the timer event may be queued late or not at all.
// Release the sticky key if the timer should've run out in the meantime.
if (sticky_key->release_at != 0 && ev->timestamp > sticky_key->release_at) {
stop_timer(sticky_key);
release_sticky_key_behavior(sticky_key, sticky_key->release_at);
continue;
}
if (ev->state) { // key down
if (sticky_key->modified_key_usage_page != 0 || sticky_key->modified_key_keycode != 0) {
// this sticky key is already in use for a keycode
continue;
}
if (sticky_key->timer_started) {
stop_timer(sticky_key);
}
sticky_key->modified_key_usage_page = ev->usage_page;
sticky_key->modified_key_keycode = ev->keycode;
} else { // key up
if (sticky_key->timer_started &&
sticky_key->modified_key_usage_page == ev->usage_page &&
sticky_key->modified_key_keycode == ev->keycode) {
stop_timer(sticky_key);
release_sticky_key_behavior(sticky_key, ev->timestamp);
}
}
}
return ZMK_EV_EVENT_BUBBLE;
}
ZMK_LISTENER(behavior_sticky_key, sticky_key_keycode_state_changed_listener);
ZMK_SUBSCRIPTION(behavior_sticky_key, zmk_keycode_state_changed);
void behavior_sticky_key_timer_handler(struct k_work *item) {
struct active_sticky_key *sticky_key =
CONTAINER_OF(item, struct active_sticky_key, release_timer);
if (sticky_key->position == ZMK_BHV_STICKY_KEY_POSITION_FREE) {
return;
}
if (sticky_key->timer_cancelled) {
sticky_key->timer_cancelled = false;
} else {
release_sticky_key_behavior(sticky_key, sticky_key->release_at);
}
}
static int behavior_sticky_key_init(const struct device *dev) {
static bool init_first_run = true;
if (init_first_run) {
for (int i = 0; i < ZMK_BHV_STICKY_KEY_MAX_HELD; i++) {
k_delayed_work_init(&active_sticky_keys[i].release_timer,
behavior_sticky_key_timer_handler);
active_sticky_keys[i].position = ZMK_BHV_STICKY_KEY_POSITION_FREE;
}
}
init_first_run = false;
return 0;
}
struct behavior_sticky_key_data {};
static struct behavior_sticky_key_data behavior_sticky_key_data;
#define _TRANSFORM_ENTRY(idx, node) \
{ \
.behavior_dev = DT_LABEL(DT_INST_PHANDLE_BY_IDX(node, bindings, idx)), \
.param1 = COND_CODE_0(DT_INST_PHA_HAS_CELL_AT_IDX(node, bindings, idx, param1), (0), \
(DT_INST_PHA_BY_IDX(node, bindings, idx, param1))), \
.param2 = COND_CODE_0(DT_INST_PHA_HAS_CELL_AT_IDX(node, bindings, idx, param2), (0), \
(DT_INST_PHA_BY_IDX(node, bindings, idx, param2))), \
},
#define KP_INST(n) \
static struct behavior_sticky_key_config behavior_sticky_key_config_##n = { \
.behavior = _TRANSFORM_ENTRY(0, n).release_after_ms = DT_INST_PROP(n, release_after_ms), \
}; \
DEVICE_AND_API_INIT(behavior_sticky_key_##n, DT_INST_LABEL(n), behavior_sticky_key_init, \
&behavior_sticky_key_data, &behavior_sticky_key_config_##n, APPLICATION, \
CONFIG_KERNEL_INIT_PRIORITY_DEFAULT, &behavior_sticky_key_driver_api);
DT_INST_FOREACH_STATUS_OKAY(KP_INST)
#endif