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// Copyright 2016 Jack Humbert
// Copyright 2019 Wojciech Siewierski < wojciech dot siewierski at onet dot pl >
// Copyright 2023 Christopher Courtney, aka Drashna Jael're (@drashna) <drashna@live.com>
// SPDX-License-Identifier: GPL-2.0-or-later
#include "keyrecords/dynamic_macros.h"
#include "keyrecords/process_records.h"
#include "wait.h"
#include "debug.h"
#include "eeprom.h"
#include "eeconfig.h"
#include <string.h>
static uint8_t macro_id = 255;
static uint8_t recording_state = STATE_NOT_RECORDING;
#if EECONFIG_USER_DATA_SIZE < 4
# error "EECONFIG_USER_DATA_SIZE not set. Don't step on others eeprom."
#endif
#ifndef DYNAMIC_MACRO_EEPROM_BLOCK0_ADDR
# define DYNAMIC_MACRO_EEPROM_BLOCK0_ADDR (uint8_t*)(EECONFIG_USER_DATABLOCK + 4)
#endif
dynamic_macro_t dynamic_macros[DYNAMIC_MACRO_COUNT];
_Static_assert((sizeof(dynamic_macros)) <= (EECONFIG_USER_DATA_SIZE - 4), "User Data Size must be large enough to host all macros");
__attribute__((weak)) void dynamic_macro_record_start_user(void) {}
__attribute__((weak)) void dynamic_macro_play_user(uint8_t macro_id) {}
__attribute__((weak)) void dynamic_macro_record_key_user(uint8_t macro_id, keyrecord_t* record) {}
__attribute__((weak)) void dynamic_macro_record_end_user(uint8_t macro_id) {}
/**
* @brief Gets the current macro ID
*
* @return uint8_t
*/
uint8_t dynamic_macro_get_current_id(void) {
return macro_id;
}
/**
* @brief Gets the current recording state
*
* @return uint8_t
*/
uint8_t dynamic_macro_get_recording_state(void) {
return recording_state;
}
/**
* Start recording of the dynamic macro.
*
* @param macro_id[in] The id of macro to be recorded
*/
bool dynamic_macro_record_start(uint8_t macro_id) {
if (macro_id >= (uint8_t)(DYNAMIC_MACRO_COUNT)) {
return false;
}
dprintf("dynamic macro recording: started for slot %d\n", macro_id);
dynamic_macro_record_start_user();
clear_keyboard();
layer_clear();
dynamic_macros[macro_id].length = 0;
return true;
}
/**
* Play the dynamic macro.
*
* @param macro_id[in] The id of macro to be played
*/
void dynamic_macro_play(uint8_t macro_id) {
if (macro_id >= (uint8_t)(DYNAMIC_MACRO_COUNT)) {
return;
}
dprintf("dynamic macro: slot %d playback, length %d\n", macro_id, dynamic_macros[macro_id].length);
layer_state_t saved_layer_state = layer_state;
clear_keyboard();
layer_clear();
for (uint8_t i = 0; i < dynamic_macros[macro_id].length; ++i) {
process_record(&dynamic_macros[macro_id].events[i]);
}
clear_keyboard();
layer_state_set(saved_layer_state);
dynamic_macro_play_user(macro_id);
}
/**
* Record a single key in a dynamic macro.
*
* @param macro_id[in] The start of the used macro buffer.
* @param record[in] The current keypress.
*/
void dynamic_macro_record_key(uint8_t macro_id, keyrecord_t* record) {
dynamic_macro_t* macro = &dynamic_macros[macro_id];
uint8_t length = macro->length;
/* If we've just started recording, ignore all the key releases. */
if (!record->event.pressed && length == 0) {
dprintln("dynamic macro: ignoring a leading key-up event");
return;
}
if (length < DYNAMIC_MACRO_SIZE) {
macro->events[length] = *record;
macro->length = ++length;
} else {
dynamic_macro_record_key_user(macro_id, record);
}
dprintf("dynamic macro: slot %d length: %d/%d\n", macro_id, length, DYNAMIC_MACRO_SIZE);
}
/**
* End recording of the dynamic macro. Essentially just update the
* pointer to the end of the macro.
*/
void dynamic_macro_record_end(uint8_t macro_id) {
if (macro_id >= (uint8_t)(DYNAMIC_MACRO_COUNT)) {
return;
}
dynamic_macro_record_end_user(macro_id);
dynamic_macro_t* macro = &dynamic_macros[macro_id];
uint8_t length = macro->length;
keyrecord_t* events_begin = &(macro->events[0]);
keyrecord_t* events_pointer = &(macro->events[length - 1]);
dprintf("dynamic_macro: macro length before trimming: %d\n", macro->length);
while (events_pointer != events_begin && (events_pointer)->event.pressed) {
dprintln("dynamic macro: trimming a trailing key-down event");
--(macro->length);
--events_pointer;
}
macro->checksum = dynamic_macro_calc_crc(macro);
dynamic_macro_save_eeprom(macro_id);
dprintf("dynamic macro: slot %d saved, length: %d\n", macro_id, length);
}
bool process_record_dynamic_macro(uint16_t keycode, keyrecord_t* record) {
if (STATE_NOT_RECORDING == recording_state) {
/* Program key pressed to request programming mode */
if (keycode == DYN_MACRO_PROG && record->event.pressed) {
// dynamic_macro_led_blink();
recording_state = STATE_RECORD_KEY_PRESSED;
dprintf("dynamic macro: programming key pressed, waiting for macro slot selection. %d\n", recording_state);
return false;
}
/* Macro key pressed to request macro playback */
if (IS_DYN_KEYCODE(keycode) && record->event.pressed) {
dynamic_macro_play(keycode - DYN_MACRO_KEY00);
return false;
}
/* Non-dynamic macro key, process it elsewhere. */
return true;
} else if (STATE_RECORD_KEY_PRESSED == recording_state) {
/* Program key pressed again before a macro selector key, cancel macro recording.
Blink leds to indicate cancelation. */
if (keycode == DYN_MACRO_PROG && record->event.pressed) {
// dynamic_macro_led_blink();
recording_state = STATE_NOT_RECORDING;
dprintf("dynamic macro: programming key pressed, programming mode canceled. %d\n", recording_state);
return false;
} else if (IS_DYN_KEYCODE(keycode) && record->event.pressed) {
macro_id = keycode - DYN_MACRO_KEY00;
if (dynamic_macro_record_start(macro_id)) {
/* Macro slot selected, enter recording state. */
recording_state = STATE_CURRENTLY_RECORDING;
} else {
recording_state = STATE_NOT_RECORDING;
}
return false;
}
/* Ignore any non-macro key press while in RECORD_KEY_PRESSED state. */
return false;
} else if (STATE_CURRENTLY_RECORDING == recording_state) {
/* Program key pressed to request end of macro recording. */
if (keycode == DYN_MACRO_PROG && record->event.pressed) {
dynamic_macro_record_end(macro_id);
recording_state = STATE_NOT_RECORDING;
return false;
}
/* Don't record other macro key presses. */
else if (IS_DYN_KEYCODE(keycode) && record->event.pressed) {
dprintln("dynamic macro: playback key ignored in programming mode.");
return false;
}
/* Non-macro keypress that should be recorded */
else {
dynamic_macro_record_key(macro_id, record);
/* Don't output recorded keypress. */
return false;
}
}
return true;
}
static inline uint16_t crc16_update(uint16_t crc, uint8_t a) {
crc ^= a;
for (uint8_t i = 0; i < 8; ++i) {
if (crc & 1)
crc = (crc >> 1) ^ 0xA001;
else
crc = (crc >> 1);
}
return crc;
}
uint16_t dynamic_macro_calc_crc(dynamic_macro_t* macro) {
uint16_t crc = 0;
uint8_t* data = (uint8_t*)macro;
for (uint16_t i = 0; i < DYNAMIC_MACRO_CRC_LENGTH; ++i) {
crc = crc16_update(crc, *(data++));
}
return crc;
}
inline void* dynamic_macro_eeprom_macro_addr(uint8_t macro_id) {
return DYNAMIC_MACRO_EEPROM_BLOCK0_ADDR + sizeof(dynamic_macro_t) * macro_id;
}
void dynamic_macro_load_eeprom_all(void) {
for (uint8_t i = 0; i < DYNAMIC_MACRO_COUNT; ++i) {
dynamic_macro_load_eeprom(i);
}
}
void dynamic_macro_load_eeprom(uint8_t macro_id) {
dynamic_macro_t* dst = &dynamic_macros[macro_id];
eeprom_read_block(dst, dynamic_macro_eeprom_macro_addr(macro_id), sizeof(dynamic_macro_t));
/* Validate checksum, ifchecksum is NOT valid for macro, set its length to 0 to prevent its use. */
if (dynamic_macro_calc_crc(dst) != dst->checksum) {
dprintf("dynamic macro: slot %d not loaded, checksum mismatch\n", macro_id);
dst->length = 0;
return;
}
dprintf("dynamic macro: slot %d loaded from eeprom, checksum okay\n", macro_id);
}
void dynamic_macro_save_eeprom(uint8_t macro_id) {
dynamic_macro_t* src = &dynamic_macros[macro_id];
eeprom_update_block(src, dynamic_macro_eeprom_macro_addr(macro_id), sizeof(dynamic_macro_t));
dprintf("dynamic macro: slot %d saved to eeprom\n", macro_id);
}
void dynamic_macro_init(void) {
/* zero out macro blocks */
memset(&dynamic_macros, 0, DYNAMIC_MACRO_COUNT * sizeof(dynamic_macro_t));
dynamic_macro_load_eeprom_all();
}
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