#include #include "keyboard.h" #include "action.h" #include "util.h" #include "action_layer.h" #ifdef DEBUG_ACTION # include "debug.h" #else # include "nodebug.h" #endif /** \brief Default Layer State */ layer_state_t default_layer_state = 0; /** \brief Default Layer State Set At user Level * * Run user code on default layer state change */ __attribute__((weak)) layer_state_t default_layer_state_set_user(layer_state_t state) { return state; } /** \brief Default Layer State Set At Keyboard Level * * Run keyboard code on default layer state change */ __attribute__((weak)) layer_state_t default_layer_state_set_kb(layer_state_t state) { return default_layer_state_set_user(state); } /** \brief Default Layer State Set * * Static function to set the default layer state, prints debug info and clears keys */ static void default_layer_state_set(layer_state_t state) { state = default_layer_state_set_kb(state); debug("default_layer_state: "); default_layer_debug(); debug(" to "); default_layer_state = state; default_layer_debug(); debug("\n"); #ifdef STRICT_LAYER_RELEASE clear_keyboard_but_mods(); // To avoid stuck keys #else clear_keyboard_but_mods_and_keys(); // Don't reset held keys #endif } /** \brief Default Layer Print * * Print out the hex value of the 32-bit default layer state, as well as the value of the highest bit. */ void default_layer_debug(void) { dprintf("%08lX(%u)", default_layer_state, get_highest_layer(default_layer_state)); } /** \brief Default Layer Set * * Sets the default layer state. */ void default_layer_set(layer_state_t state) { default_layer_state_set(state); } #ifndef NO_ACTION_LAYER /** \brief Default Layer Or * * Turns on the default layer based on matching bits between specifed layer and existing layer state */ void default_layer_or(layer_state_t state) { default_layer_state_set(default_layer_state | state); } /** \brief Default Layer And * * Turns on default layer based on matching enabled bits between specifed layer and existing layer state */ void default_layer_and(layer_state_t state) { default_layer_state_set(default_layer_state & state); } /** \brief Default Layer Xor * * Turns on default layer based on non-matching bits between specifed layer and existing layer state */ void default_layer_xor(layer_state_t state) { default_layer_state_set(default_layer_state ^ state); } #endif #ifndef NO_ACTION_LAYER /** \brief Keymap Layer State */ layer_state_t layer_state = 0; /** \brief Layer state set user * * Runs user code on layer state change */ __attribute__((weak)) layer_state_t layer_state_set_user(layer_state_t state) { return state; } /** \brief Layer state set keyboard * * Runs keyboard code on layer state change */ __attribute__((weak)) layer_state_t layer_state_set_kb(layer_state_t state) { return layer_state_set_user(state); } /** \brief Layer state set * * Sets the layer to match the specifed state (a bitmask) */ void layer_state_set(layer_state_t state) { state = layer_state_set_kb(state); dprint("layer_state: "); layer_debug(); dprint(" to "); layer_state = state; layer_debug(); dprintln(); # ifdef STRICT_LAYER_RELEASE clear_keyboard_but_mods(); // To avoid stuck keys # else clear_keyboard_but_mods_and_keys(); // Don't reset held keys # endif } /** \brief Layer clear * * Turn off all layers */ void layer_clear(void) { layer_state_set(0); } /** \brief Layer state is * * Return whether the given state is on (it might still be shadowed by a higher state, though) */ bool layer_state_is(uint8_t layer) { return layer_state_cmp(layer_state, layer); } /** \brief Layer state compare * * Used for comparing layers {mostly used for unit testing} */ bool layer_state_cmp(layer_state_t cmp_layer_state, uint8_t layer) { if (!cmp_layer_state) { return layer == 0; } return (cmp_layer_state & ((layer_state_t)1 << layer)) != 0; } /** \brief Layer move * * Turns on the given layer and turn off all other layers */ void layer_move(uint8_t layer) { layer_state_set((layer_state_t)1 << layer); } /** \brief Layer on * * Turns on given layer */ void layer_on(uint8_t layer) { layer_state_set(layer_state | ((layer_state_t)1 << layer)); } /** \brief Layer off * * Turns off given layer */ void layer_off(uint8_t layer) { layer_state_set(layer_state & ~((layer_state_t)1 << layer)); } /** \brief Layer invert * * Toggle the given layer (set it if it's unset, or unset it if it's set) */ void layer_invert(uint8_t layer) { layer_state_set(layer_state ^ ((layer_state_t)1 << layer)); } /** \brief Layer or * * Turns on layers based on matching bits between specifed layer and existing layer state */ void layer_or(layer_state_t state) { layer_state_set(layer_state | state); } /** \brief Layer and * * Turns on layers based on matching enabled bits between specifed layer and existing layer state */ void layer_and(layer_state_t state) { layer_state_set(layer_state & state); } /** \brief Layer xor * * Turns on layers based on non-matching bits between specifed layer and existing layer state */ void layer_xor(layer_state_t state) { layer_state_set(layer_state ^ state); } /** \brief Layer debug printing * * Print out the hex value of the 32-bit layer state, as well as the value of the highest bit. */ void layer_debug(void) { dprintf("%08lX(%u)", layer_state, get_highest_layer(layer_state)); } #endif #if !defined(NO_ACTION_LAYER) && !defined(STRICT_LAYER_RELEASE) /** \brief source layer cache */ uint8_t source_layers_cache[(MATRIX_ROWS * MATRIX_COLS + 7) / 8][MAX_LAYER_BITS] = {{0}}; /** \brief update source layers cache * * Updates the cached keys when changing layers */ void update_source_layers_cache(keypos_t key, uint8_t layer) { const uint8_t key_number = key.col + (key.row * MATRIX_COLS); const uint8_t storage_row = key_number / 8; const uint8_t storage_bit = key_number % 8; for (uint8_t bit_number = 0; bit_number < MAX_LAYER_BITS; bit_number++) { source_layers_cache[storage_row][bit_number] ^= (-((layer & (1U << bit_number)) != 0) ^ source_layers_cache[storage_row][bit_number]) & (1U << storage_bit); } } /** \brief read source layers cache * * reads the cached keys stored when the layer was changed */ uint8_t read_source_layers_cache(keypos_t key) { const uint8_t key_number = key.col + (key.row * MATRIX_COLS); const uint8_t storage_row = key_number / 8; const uint8_t storage_bit = key_number % 8; uint8_t layer = 0; for (uint8_t bit_number = 0; bit_number < MAX_LAYER_BITS; bit_number++) { layer |= ((source_layers_cache[storage_row][bit_number] & (1U << storage_bit)) != 0) << bit_number; } return layer; } #endif /** \brief Store or get action (FIXME: Needs better summary) * * Make sure the action triggered when the key is released is the same * one as the one triggered on press. It's important for the mod keys * when the layer is switched after the down event but before the up * event as they may get stuck otherwise. */ action_t store_or_get_action(bool pressed, keypos_t key) { #if !defined(NO_ACTION_LAYER) && !defined(STRICT_LAYER_RELEASE) if (disable_action_cache) { return layer_switch_get_action(key); } uint8_t layer; if (pressed) { layer = layer_switch_get_layer(key); update_source_layers_cache(key, layer); } else { layer = read_source_layers_cache(key); } return action_for_key(layer, key); #else return layer_switch_get_action(key); #endif } /** \brief Layer switch get layer * * Gets the layer based on key info */ uint8_t layer_switch_get_layer(keypos_t key) { #ifndef NO_ACTION_LAYER action_t action; action.code = ACTION_TRANSPARENT; layer_state_t layers = layer_state | default_layer_state; /* check top layer first */ for (int8_t i = MAX_LAYER - 1; i >= 0; i--) { if (layers & ((layer_state_t)1 << i)) { action = action_for_key(i, key); if (action.code != ACTION_TRANSPARENT) { return i; } } } /* fall back to layer 0 */ return 0; #else return get_highest_layer(default_layer_state); #endif } /** \brief Layer switch get layer * * Gets action code based on key position */ action_t layer_switch_get_action(keypos_t key) { return action_for_key(layer_switch_get_layer(key), key); }