qmk_firmware/keyboards/cannonkeys/satisfaction75/satisfaction75.c
Nick Brassel a0089aa345
Fixup Satisfaction75 bootprocess. (#12621)
- Use normal ChibiOS I2C driver.
- Move drawing code to housekeeping -- previously it was during matrix
  scan, which gets executed during bootmagic checks. However, bootmagic
  is invoked before QWIIC subsystem is enabled, which means I2C isn't
  configured yet. All I2C calls to the OLED fail with timeouts while
  bootmagic is being checked. Housekeeping ensures this is executed once
  the system has initialised and settled.
- QWIIC OLED driver: properly clear out OLED buffer when clearing screen.
2021-04-19 13:08:01 +10:00

454 lines
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12 KiB
C

#include "satisfaction75.h"
#include "print.h"
#include "debug.h"
#include <ch.h>
#include <hal.h>
#ifdef QWIIC_MICRO_OLED_ENABLE
#include "micro_oled.h"
#include "qwiic.h"
#endif
#include "timer.h"
#include "raw_hid.h"
#include "dynamic_keymap.h"
#include "tmk_core/common/eeprom.h"
#include "version.h" // for QMK_BUILDDATE used in EEPROM magic
/* Artificial delay added to get media keys to work in the encoder*/
#define MEDIA_KEY_DELAY 10
uint16_t last_flush;
volatile uint8_t led_numlock = false;
volatile uint8_t led_capslock = false;
volatile uint8_t led_scrolllock = false;
uint8_t layer;
bool queue_for_send = false;
bool clock_set_mode = false;
uint8_t oled_mode = OLED_DEFAULT;
bool oled_sleeping = false;
uint8_t encoder_value = 32;
uint8_t encoder_mode = ENC_MODE_VOLUME;
uint8_t enabled_encoder_modes = 0x1F;
RTCDateTime last_timespec;
uint16_t last_minute = 0;
uint8_t time_config_idx = 0;
int8_t hour_config = 0;
int16_t minute_config = 0;
int8_t year_config = 0;
int8_t month_config = 0;
int8_t day_config = 0;
uint8_t previous_encoder_mode = 0;
backlight_config_t kb_backlight_config = {
.enable = true,
.breathing = true,
.level = BACKLIGHT_LEVELS
};
void board_init(void) {
SYSCFG->CFGR1 |= SYSCFG_CFGR1_I2C1_DMA_RMP;
SYSCFG->CFGR1 &= ~(SYSCFG_CFGR1_SPI2_DMA_RMP);
}
#ifdef VIA_ENABLE
void backlight_get_value( uint8_t *data )
{
uint8_t *value_id = &(data[0]);
uint8_t *value_data = &(data[1]);
switch (*value_id)
{
case id_qmk_backlight_brightness:
{
// level / BACKLIGHT_LEVELS * 255
value_data[0] = ((uint16_t)kb_backlight_config.level) * 255 / BACKLIGHT_LEVELS;
break;
}
case id_qmk_backlight_effect:
{
value_data[0] = kb_backlight_config.breathing ? 1 : 0;
break;
}
}
}
void backlight_set_value( uint8_t *data )
{
uint8_t *value_id = &(data[0]);
uint8_t *value_data = &(data[1]);
switch (*value_id)
{
case id_qmk_backlight_brightness:
{
// level / 255 * BACKLIGHT_LEVELS
kb_backlight_config.level = ((uint16_t)value_data[0]) * BACKLIGHT_LEVELS / 255;
backlight_set(kb_backlight_config.level);
break;
}
case id_qmk_backlight_effect:
{
if ( value_data[0] == 0 ) {
kb_backlight_config.breathing = false;
breathing_disable();
} else {
kb_backlight_config.breathing = true;
breathing_enable();
}
break;
}
}
}
void raw_hid_receive_kb( uint8_t *data, uint8_t length )
{
uint8_t *command_id = &(data[0]);
uint8_t *command_data = &(data[1]);
switch ( *command_id )
{
case id_get_keyboard_value:
{
switch( command_data[0])
{
case id_oled_default_mode:
{
uint8_t default_oled = eeprom_read_byte((uint8_t*)EEPROM_DEFAULT_OLED);
command_data[1] = default_oled;
break;
}
case id_oled_mode:
{
command_data[1] = oled_mode;
break;
}
case id_encoder_modes:
{
command_data[1] = enabled_encoder_modes;
break;
}
case id_encoder_custom:
{
uint8_t custom_encoder_idx = command_data[1];
uint16_t keycode = retrieve_custom_encoder_config(custom_encoder_idx, ENC_CUSTOM_CW);
command_data[2] = keycode >> 8;
command_data[3] = keycode & 0xFF;
keycode = retrieve_custom_encoder_config(custom_encoder_idx, ENC_CUSTOM_CCW);
command_data[4] = keycode >> 8;
command_data[5] = keycode & 0xFF;
keycode = retrieve_custom_encoder_config(custom_encoder_idx, ENC_CUSTOM_PRESS);
command_data[6] = keycode >> 8;
command_data[7] = keycode & 0xFF;
break;
}
default:
{
*command_id = id_unhandled;
break;
}
}
break;
}
case id_set_keyboard_value:
{
switch(command_data[0]){
case id_oled_default_mode:
{
eeprom_update_byte((uint8_t*)EEPROM_DEFAULT_OLED, command_data[1]);
break;
}
case id_oled_mode:
{
oled_mode = command_data[1];
draw_ui();
break;
}
case id_encoder_modes:
{
enabled_encoder_modes = command_data[1];
eeprom_update_byte((uint8_t*)EEPROM_ENABLED_ENCODER_MODES, enabled_encoder_modes);
break;
}
case id_encoder_custom:
{
uint8_t custom_encoder_idx = command_data[1];
uint8_t encoder_behavior = command_data[2];
uint16_t keycode = (command_data[3] << 8) | command_data[4];
set_custom_encoder_config(custom_encoder_idx, encoder_behavior, keycode);
break;
}
default:
{
*command_id = id_unhandled;
break;
}
}
break;
}
case id_lighting_set_value:
{
backlight_set_value(command_data);
break;
}
case id_lighting_get_value:
{
backlight_get_value(command_data);
break;
}
case id_lighting_save:
{
backlight_config_save();
break;
}
default:
{
// Unhandled message.
*command_id = id_unhandled;
break;
}
}
// DO NOT call raw_hid_send(data,length) here, let caller do this
}
#endif
void read_host_led_state(void) {
uint8_t leds = host_keyboard_leds();
if (leds & (1 << USB_LED_NUM_LOCK)) {
if (led_numlock == false){
led_numlock = true;}
} else {
if (led_numlock == true){
led_numlock = false;}
}
if (leds & (1 << USB_LED_CAPS_LOCK)) {
if (led_capslock == false){
led_capslock = true;}
} else {
if (led_capslock == true){
led_capslock = false;}
}
if (leds & (1 << USB_LED_SCROLL_LOCK)) {
if (led_scrolllock == false){
led_scrolllock = true;}
} else {
if (led_scrolllock == true){
led_scrolllock = false;}
}
}
uint32_t layer_state_set_kb(uint32_t state) {
state = layer_state_set_user(state);
layer = biton32(state);
queue_for_send = true;
return state;
}
bool process_record_kb(uint16_t keycode, keyrecord_t *record) {
queue_for_send = true;
switch (keycode) {
case OLED_TOGG:
if(!clock_set_mode){
if (record->event.pressed) {
oled_mode = (oled_mode + 1) % _NUM_OLED_MODES;
draw_ui();
}
}
return false;
case CLOCK_SET:
if (record->event.pressed) {
if(clock_set_mode){
pre_encoder_mode_change();
clock_set_mode = false;
encoder_mode = previous_encoder_mode;
post_encoder_mode_change();
}else{
previous_encoder_mode = encoder_mode;
pre_encoder_mode_change();
clock_set_mode = true;
encoder_mode = ENC_MODE_CLOCK_SET;
post_encoder_mode_change();
}
}
return false;
case ENC_PRESS:
if (record->event.pressed) {
uint16_t mapped_code = handle_encoder_press();
uint16_t held_keycode_timer = timer_read();
if(mapped_code != 0){
register_code16(mapped_code);
while (timer_elapsed(held_keycode_timer) < MEDIA_KEY_DELAY){ /* no-op */ }
unregister_code16(mapped_code);
}
} else {
// Do something else when release
}
return false;
default:
break;
}
return process_record_user(keycode, record);
}
void encoder_update_kb(uint8_t index, bool clockwise) {
encoder_value = (encoder_value + (clockwise ? 1 : -1)) % 64;
queue_for_send = true;
if (index == 0) {
if (layer == 0){
uint16_t mapped_code = 0;
if (clockwise) {
mapped_code = handle_encoder_clockwise();
} else {
mapped_code = handle_encoder_ccw();
}
uint16_t held_keycode_timer = timer_read();
if(mapped_code != 0){
register_code16(mapped_code);
while (timer_elapsed(held_keycode_timer) < MEDIA_KEY_DELAY){ /* no-op */ }
unregister_code16(mapped_code);
}
} else {
if(clockwise){
change_encoder_mode(false);
} else {
change_encoder_mode(true);
}
}
}
}
void custom_config_reset(void){
void *p = (void*)(VIA_EEPROM_CUSTOM_CONFIG_ADDR);
void *end = (void*)(VIA_EEPROM_CUSTOM_CONFIG_ADDR+VIA_EEPROM_CUSTOM_CONFIG_SIZE);
while ( p != end ) {
eeprom_update_byte(p, 0);
++p;
}
eeprom_update_byte((uint8_t*)EEPROM_ENABLED_ENCODER_MODES, 0x1F);
}
void backlight_config_save(){
eeprom_update_byte((uint8_t*)EEPROM_CUSTOM_BACKLIGHT, kb_backlight_config.raw);
}
void custom_config_load(){
kb_backlight_config.raw = eeprom_read_byte((uint8_t*)EEPROM_CUSTOM_BACKLIGHT);
#ifdef DYNAMIC_KEYMAP_ENABLE
oled_mode = eeprom_read_byte((uint8_t*)EEPROM_DEFAULT_OLED);
enabled_encoder_modes = eeprom_read_byte((uint8_t*)EEPROM_ENABLED_ENCODER_MODES);
#endif
}
// Called from via_init() if VIA_ENABLE
// Called from matrix_init_kb() if not VIA_ENABLE
void via_init_kb(void)
{
// If the EEPROM has the magic, the data is good.
// OK to load from EEPROM.
if (via_eeprom_is_valid()) {
custom_config_load();
} else {
#ifdef DYNAMIC_KEYMAP_ENABLE
// Reset the custom stuff
custom_config_reset();
#endif
// DO NOT set EEPROM valid here, let caller do this
}
}
void matrix_init_kb(void)
{
#ifndef VIA_ENABLE
via_init_kb();
via_eeprom_set_valid(true);
#endif // VIA_ENABLE
rtcGetTime(&RTCD1, &last_timespec);
queue_for_send = true;
backlight_init_ports();
matrix_init_user();
}
void housekeeping_task_kb(void) {
rtcGetTime(&RTCD1, &last_timespec);
uint16_t minutes_since_midnight = last_timespec.millisecond / 1000 / 60;
if (minutes_since_midnight != last_minute){
last_minute = minutes_since_midnight;
if(!oled_sleeping){
queue_for_send = true;
}
}
#ifdef QWIIC_MICRO_OLED_ENABLE
if (queue_for_send && oled_mode != OLED_OFF) {
oled_sleeping = false;
read_host_led_state();
draw_ui();
queue_for_send = false;
}
if (timer_elapsed(last_flush) > ScreenOffInterval && !oled_sleeping) {
send_command(DISPLAYOFF); /* 0xAE */
oled_sleeping = true;
}
#endif
}
//
// In the case of VIA being disabled, we still need to check if
// keyboard level EEPROM memory is valid before loading.
// Thus these are copies of the same functions in VIA, since
// the backlight settings reuse VIA's EEPROM magic/version,
// and the ones in via.c won't be compiled in.
//
// Yes, this is sub-optimal, and is only here for completeness
// (i.e. catering to the 1% of people that want wilba.tech LED bling
// AND want persistent settings BUT DON'T want to use dynamic keymaps/VIA).
//
#ifndef VIA_ENABLE
bool via_eeprom_is_valid(void)
{
char *p = QMK_BUILDDATE; // e.g. "2019-11-05-11:29:54"
uint8_t magic0 = ( ( p[2] & 0x0F ) << 4 ) | ( p[3] & 0x0F );
uint8_t magic1 = ( ( p[5] & 0x0F ) << 4 ) | ( p[6] & 0x0F );
uint8_t magic2 = ( ( p[8] & 0x0F ) << 4 ) | ( p[9] & 0x0F );
return (eeprom_read_byte( (void*)VIA_EEPROM_MAGIC_ADDR+0 ) == magic0 &&
eeprom_read_byte( (void*)VIA_EEPROM_MAGIC_ADDR+1 ) == magic1 &&
eeprom_read_byte( (void*)VIA_EEPROM_MAGIC_ADDR+2 ) == magic2 );
}
// Sets VIA/keyboard level usage of EEPROM to valid/invalid
// Keyboard level code (eg. via_init_kb()) should not call this
void via_eeprom_set_valid(bool valid)
{
char *p = QMK_BUILDDATE; // e.g. "2019-11-05-11:29:54"
uint8_t magic0 = ( ( p[2] & 0x0F ) << 4 ) | ( p[3] & 0x0F );
uint8_t magic1 = ( ( p[5] & 0x0F ) << 4 ) | ( p[6] & 0x0F );
uint8_t magic2 = ( ( p[8] & 0x0F ) << 4 ) | ( p[9] & 0x0F );
eeprom_update_byte( (void*)VIA_EEPROM_MAGIC_ADDR+0, valid ? magic0 : 0xFF);
eeprom_update_byte( (void*)VIA_EEPROM_MAGIC_ADDR+1, valid ? magic1 : 0xFF);
eeprom_update_byte( (void*)VIA_EEPROM_MAGIC_ADDR+2, valid ? magic2 : 0xFF);
}
void via_eeprom_reset(void)
{
// Set the VIA specific EEPROM state as invalid.
via_eeprom_set_valid(false);
// Set the TMK/QMK EEPROM state as invalid.
eeconfig_disable();
}
#endif // VIA_ENABLE