non working code

muon_light_dc
Jack Humbert 7 years ago
parent 1b7efbc03b
commit cca90f4389

@ -75,11 +75,6 @@ void twi2c_catch_error(I2CDriver *i2cp)
/**
* Callback after sending of response complete - restores default reply in case polled
*/
void twi2c_clear_after_send(I2CDriver *i2cp)
{
// echoReply.size = 0; // Clear receive message
// i2cSlaveReplyI(i2cp, &initialReply);
}
uint8_t twi2c_start(void) {
i2cStart(&I2C_DRIVER, &i2cconfig);
@ -100,11 +95,11 @@ void twi2c_init(void) {
}
uint8_t twi2c_write(uint8_t data) {
return i2cMasterTransmitTimeout(&I2C_DRIVER, twi2c_address/2, &data, 1, 0, 0, MS2ST(100));
return i2cMasterTransmitTimeout(&I2C_DRIVER, twi2c_address/2, &data, 1, NULL, 0, MS2ST(100));
}
uint8_t twi2c_transmit(uint8_t address, uint8_t * data, uint16_t length) {
return i2cMasterTransmitTimeout(&I2C_DRIVER, address/2, data, length, 0, 0, MS2ST(100));
return i2cMasterTransmitTimeout(&I2C_DRIVER, address/2, data, length, NULL, 0, MS2ST(100));
}
uint8_t twi2c_receive(uint8_t address, uint8_t * data, uint16_t length) {
@ -112,8 +107,8 @@ uint8_t twi2c_receive(uint8_t address, uint8_t * data, uint16_t length) {
}
uint8_t twi2c_incoming_body[50];
uint8_t twi2c_outgoing_body[1024];
uint8_t twi2c_incoming_body[50] = {0};
uint8_t twi2c_outgoing_body[1024] = {0};
// Response to received messages
I2CSlaveMsg twi2c_incoming_message = {
@ -138,6 +133,11 @@ I2CSlaveMsg twi2c_outgoing_message = {
twi2c_catch_error
};
void twi2c_clear_after_send(I2CDriver *i2cp) {
twi2c_outgoing_message.size = 0; // Clear receive message
//i2cSlaveReplyI(i2cp, &initialReply);
}
uint8_t twi2c_reply(I2CDriver * i2cp, uint8_t * data, uint16_t length) {
memcpy(twi2c_outgoing_body, data, length);
twi2c_outgoing_message.size = length;
@ -157,11 +157,26 @@ uint8_t twi2c_start_listening(uint8_t address, twi2c_message_received callback)
return 0;
}
uint8_t twi2c_restart_listening(uint8_t address) {
uint8_t twi2c_remove_listening(uint8_t address) {
i2cUnmatchAddress(&I2C_DRIVER, address/2);
return 0;
}
uint8_t twi2c_add_listening(uint8_t address) {
i2cMatchAddress(&I2C_DRIVER, address/2);
return 0;
}
uint8_t twi2c_remove_listening_i(uint8_t address) {
i2cUnmatchAddressI(&I2C_DRIVER, address/2);
return 0;
}
uint8_t twi2c_add_listening_i(uint8_t address) {
i2cMatchAddressI(&I2C_DRIVER, address/2);
return 0;
}
void twi2c_stop(void) {
i2cUnmatchAll(&I2C_DRIVER);
i2cStop(&I2C_DRIVER);

@ -43,6 +43,9 @@ void twi2c_stop(void);
uint8_t twi2c_reply(I2CDriver * i2cp, uint8_t * data, uint16_t length);
uint8_t twi2c_transmit_receive(uint8_t address, uint8_t * tx_body, uint16_t tx_length, uint8_t * rx_body, uint16_t rx_length);
uint8_t twi2c_start_listening(uint8_t address, twi2c_message_received callback);
uint8_t twi2c_restart_listening(uint8_t address);
uint8_t twi2c_add_listening(uint8_t address);
uint8_t twi2c_remove_listening(uint8_t address);
uint8_t twi2c_add_listening_i(uint8_t address);
uint8_t twi2c_remove_listening_i(uint8_t address);
#endif

@ -24,28 +24,42 @@
#include "usb_driver.h"
#define QWIIC_KEYBOARD_LAYERS 16
#define QWIIC_KEYBOARD_ROWS 8
#define QWIIC_KEYBOARD_COLS 8
#define QWIIC_KEYBOARD_ROWS 8
#define QWIIC_KEYBOARD_COLS 8
#define qwiic_matrix_t uint8_t
#if (QWIIC_KEYBOARD_COLS <= 8)
typedef uint8_t qwiic_row_t;
#elif (QWIIC_KEYBOARD_COLS <= 16)
typedef uint16_t qwiic_row_t;
#elif (QWIIC_KEYBOARD_COLS <= 32)
typedef uint32_t qwiic_row_t;
#else
#error "QWIIC_KEYBOARD_COLS: invalid value"
#endif
#define QWIIC_KEYBOARD_HANDSHAKE_ADDRESS 0b01010100
#define QWIIC_KEYBOARD_LISTENING_ADDRESS_START 0b01010110
#define QWIIC_KEYBOARD_HANDSHAKE_MESSAGE_SIZE (QWIIC_KEYBOARD_LAYERS * QWIIC_KEYBOARD_ROWS * QWIIC_KEYBOARD_COLS)
#define QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE MATRIX_ROWS
#define QWIIC_KEYBOARD_MAX_DEVICES 1
#define QWIIC_KEYBOARD_KEYMAP_MESSAGE_SIZE (QWIIC_KEYBOARD_LAYERS * QWIIC_KEYBOARD_ROWS * QWIIC_KEYBOARD_COLS)
#define QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE (QWIIC_KEYBOARD_ROWS)
void qwiic_keyboard_write_keymap(uint8_t * pointer);
void qwiic_keyboard_read_keymap(uint8_t * pointer);
void qwiic_keyboard_read_keymap(uint8_t * pointer, uint8_t index);
bool qwiic_keyboard_master = false;
bool qwiic_keyboard_connected = false;
uint8_t qwiic_keyboard_handshake_message[QWIIC_KEYBOARD_HANDSHAKE_MESSAGE_SIZE] = {0};
uint8_t qwiic_keyboard_matrix_message[QWIIC_KEYBOARD_ROWS] = {0};
bool qwiic_keyboard_connected[QWIIC_KEYBOARD_MAX_DEVICES] = { false };
uint8_t qwiic_keyboard_keymap_message[QWIIC_KEYBOARD_KEYMAP_MESSAGE_SIZE] = {0};
uint8_t qwiic_keyboard_matrix_message[QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE] = {0};
twi2c_message_received qwiic_keyboard_message_received_ptr = qwiic_keyboard_message_received;
float song_one_up[][2] = SONG(ONE_UP_SOUND);
uint8_t first_message = 0;
uint16_t qwiic_keyboard_keymap[QWIIC_KEYBOARD_LAYERS][QWIIC_KEYBOARD_ROWS][QWIIC_KEYBOARD_COLS] = {0};
uint8_t qwiic_keyboard_listening_address = QWIIC_KEYBOARD_LISTENING_ADDRESS_START;
uint8_t qwiic_keyboard_processing_slave = false;
uint16_t qwiic_keyboard_keymap[QWIIC_KEYBOARD_MAX_DEVICES][QWIIC_KEYBOARD_LAYERS][QWIIC_KEYBOARD_ROWS][QWIIC_KEYBOARD_COLS] = {0};
bool qwiic_keyboard_keymap_initialised[QWIIC_KEYBOARD_MAX_DEVICES] = { false };
uint8_t qwiic_keyboard_listening_address[QWIIC_KEYBOARD_MAX_DEVICES] = { 0 };
#define QWIIC_KEYBOARD_NOT_PROCESSING 255
uint8_t qwiic_keyboard_processing_slave = QWIIC_KEYBOARD_NOT_PROCESSING;
void qwiic_keyboard_init(void) {
twi2c_init();
@ -54,106 +68,148 @@ void qwiic_keyboard_init(void) {
}
void qwiic_keyboard_set_master(void) {
twi2c_stop();
twi2c_start();
//twi2c_stop();
//twi2c_start();
twi2c_remove_listening(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS);
qwiic_keyboard_master = true;
}
uint8_t command[1] = { 0x00 };
uint8_t keymap_command[1] = { 0x01 };
uint8_t matrix_command[1] = { 0x02 };
uint8_t look_counter = 0;
// uint8_t get_available_device_index(void) {
// for (uint8_t i = 0; i < QWIIC_KEYBOARD_MAX_DEVICES; i++) {
// if (!qwiic_keyboard_connected[i])
// return i;
// }
// return 255;
// }
void qwiic_keyboard_task(void) {
if (USB_DRIVER.state == USB_ACTIVE)
qwiic_keyboard_master = true;
else
qwiic_keyboard_master = false;
qwiic_keyboard_set_master();
if (qwiic_keyboard_master) {
if (qwiic_keyboard_connected) {
// send empty message, expecting matrix info
if (MSG_OK == twi2c_transmit_receive(qwiic_keyboard_listening_address,
command, 1,
qwiic_keyboard_matrix_message, QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE
)) {
// majority of this is pulled from keyboard.c:keyboard_task()
static qwiic_matrix_t matrix_prev[QWIIC_KEYBOARD_ROWS];
qwiic_matrix_t matrix_row = 0;
qwiic_matrix_t matrix_change = 0;
#ifdef QMK_KEYS_PER_SCAN
uint8_t keys_processed = 0;
#endif
qwiic_keyboard_processing_slave = true;
for (uint8_t r = 0; r < QWIIC_KEYBOARD_ROWS; r++) {
matrix_row = qwiic_keyboard_matrix_message[r];
matrix_change = matrix_row ^ matrix_prev[r];
if (matrix_change) {
for (uint8_t c = 0; c < QWIIC_KEYBOARD_COLS; c++) {
if (matrix_change & ((qwiic_matrix_t)1<<c)) {
action_exec((keyevent_t){
.key = (keypos_t){ .row = r, .col = c },
.pressed = (matrix_row & ((qwiic_matrix_t)1<<c)),
.time = (timer_read() | 1) /* time should not be 0 */
});
// record a processed key
matrix_prev[r] ^= ((qwiic_matrix_t)1<<c);
#ifdef QMK_KEYS_PER_SCAN
// only jump out if we have processed "enough" keys.
if (++keys_processed >= QMK_KEYS_PER_SCAN)
#endif
// process a key per task call
goto QWIIC_MATRIX_LOOP_END;
for (uint8_t device_i = 0; device_i < QWIIC_KEYBOARD_MAX_DEVICES; device_i++) {
if (qwiic_keyboard_connected[device_i]) {
// send empty message, expecting matrix info
// twi2c_transmit(qwiic_keyboard_listening_address[device_i], command, 1);
// if (MSG_OK == twi2c_receive(qwiic_keyboard_listening_address[device_i],
// qwiic_keyboard_matrix_message, QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE
// )) {
if (!qwiic_keyboard_keymap_initialised[device_i]) {
if (MSG_OK == twi2c_transmit_receive(qwiic_keyboard_listening_address[device_i],
keymap_command, 1,
qwiic_keyboard_keymap_message, QWIIC_KEYBOARD_KEYMAP_MESSAGE_SIZE
)) {
// load keymap into memory
qwiic_keyboard_keymap_initialised[device_i] = true;
qwiic_keyboard_read_keymap(qwiic_keyboard_keymap_message, device_i);
}
} else {
if (MSG_OK == twi2c_transmit_receive(qwiic_keyboard_listening_address[device_i],
matrix_command, 1,
qwiic_keyboard_matrix_message, QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE
)) {
// majority of this is pulled from keyboard.c:keyboard_task()
static qwiic_row_t matrix_prev[QWIIC_KEYBOARD_ROWS];
qwiic_row_t matrix_row = 0;
qwiic_row_t matrix_change = 0;
#ifdef QMK_KEYS_PER_SCAN
uint8_t keys_processed = 0;
#endif
qwiic_keyboard_processing_slave = device_i;
for (uint8_t r = 0; r < QWIIC_KEYBOARD_ROWS; r++) {
matrix_row = qwiic_keyboard_matrix_message[r];
matrix_change = matrix_row ^ matrix_prev[r];
if (matrix_change) {
for (uint8_t c = 0; c < QWIIC_KEYBOARD_COLS; c++) {
if (matrix_change & ((qwiic_row_t)1<<c)) {
action_exec((keyevent_t){
.key = (keypos_t){ .row = r, .col = c },
.pressed = (matrix_row & ((qwiic_row_t)1<<c)),
.time = (timer_read() | 1) /* time should not be 0 */
});
// record a processed key
matrix_prev[r] ^= ((qwiic_row_t)1<<c);
#ifdef QMK_KEYS_PER_SCAN
// only jump out if we have processed "enough" keys.
if (++keys_processed >= QMK_KEYS_PER_SCAN)
#endif
// process a key per task call
goto QWIIC_MATRIX_LOOP_END;
}
}
}
}
// call with pseudo tick event when no real key event.
#ifdef QMK_KEYS_PER_SCAN
// we can get here with some keys processed now.
if (!keys_processed)
#endif
action_exec(TICK);
QWIIC_MATRIX_LOOP_END:
qwiic_keyboard_processing_slave = QWIIC_KEYBOARD_NOT_PROCESSING;
// if (first_message == 100) {
// PLAY_SONG(song_one_up);
// }
// first_message += 1;
}
}
// call with pseudo tick event when no real key event.
#ifdef QMK_KEYS_PER_SCAN
// we can get here with some keys processed now.
if (!keys_processed)
#endif
action_exec(TICK);
QWIIC_MATRIX_LOOP_END:
qwiic_keyboard_processing_slave = false;
} else {
// disconnect
// qwiic_keyboard_connected = false;
}
} else { // if not connected
// send new address to listen on, expect back keymap
if (MSG_OK == twi2c_transmit_receive(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS,
&qwiic_keyboard_listening_address, 1,
qwiic_keyboard_handshake_message, QWIIC_KEYBOARD_HANDSHAKE_MESSAGE_SIZE
)) {
qwiic_keyboard_connected = true;
// load keymap into memory
qwiic_keyboard_read_keymap(qwiic_keyboard_handshake_message);
}
}
}
} // end else - not init
} else { // if not connected
//if (look_counter == 0) {
// send new address to listen on, expect back keymap
uint8_t new_address = QWIIC_KEYBOARD_LISTENING_ADDRESS_START + (device_i*2);
uint8_t address_copy = 0;
// twi2c_transmit(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS, &new_address, 1);
// if (MSG_OK == twi2c_receive(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS,
// &address_copy, 1
// )) {
if (MSG_OK == twi2c_transmit_receive(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS,
&new_address, 1,
&address_copy, 1
)) {
send_byte(address_copy);
if (address_copy == new_address) {
SEND_STRING(".");
PLAY_SONG(song_one_up);
qwiic_keyboard_connected[device_i] = true;
qwiic_keyboard_listening_address[device_i] = new_address;
}
}
//} // end if - look for new
} // end else - connected
} // end for - devices
look_counter = ((look_counter + 1) % 150);
} // end if - master
}
float song_one_up[][2] = SONG(ONE_UP_SOUND);
bool first_message = true;
void qwiic_keyboard_message_received(I2CDriver *i2cp, uint8_t * body, uint16_t size) {
if (qwiic_keyboard_connected) {
for (uint8_t row = 0; row < QWIIC_KEYBOARD_ROWS; row++) {
if (row < MATRIX_ROWS) {
qwiic_keyboard_matrix_message[row] = matrix_get_row(row);
} else {
qwiic_keyboard_matrix_message[row] = 0;
switch (body[0]) {
// send keymap
case 0x01:
qwiic_keyboard_write_keymap(qwiic_keyboard_keymap_message);
twi2c_reply(i2cp, qwiic_keyboard_keymap_message, QWIIC_KEYBOARD_KEYMAP_MESSAGE_SIZE);
break;
// send matrix
case 0x02:
for (uint8_t row = 0; row < QWIIC_KEYBOARD_ROWS; row++) {
if (row < MATRIX_ROWS) {
qwiic_keyboard_matrix_message[row] = matrix_get_row(row);
} else {
qwiic_keyboard_matrix_message[row] = 0;
}
}
}
twi2c_reply(i2cp, qwiic_keyboard_matrix_message, QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE);
if (first_message) {
PLAY_SONG(song_one_up);
first_message = false;
}
} else {
qwiic_keyboard_connected = true;
qwiic_keyboard_master = false;
qwiic_keyboard_listening_address = body[0];
twi2c_restart_listening(qwiic_keyboard_listening_address);
qwiic_keyboard_write_keymap(qwiic_keyboard_handshake_message);
twi2c_reply(i2cp, qwiic_keyboard_handshake_message, QWIIC_KEYBOARD_HANDSHAKE_MESSAGE_SIZE);
twi2c_reply(i2cp, qwiic_keyboard_matrix_message, QWIIC_KEYBOARD_MATRIX_MESSAGE_SIZE);
break;
default:
twi2c_remove_listening_i(QWIIC_KEYBOARD_HANDSHAKE_ADDRESS);
qwiic_keyboard_connected[0] = true;
//qwiic_keyboard_master = false;
qwiic_keyboard_listening_address[0] = body[0];
twi2c_reply(i2cp, body, size);
twi2c_add_listening_i(qwiic_keyboard_listening_address[0]);
break;
}
}
@ -164,7 +220,8 @@ void qwiic_keyboard_write_keymap(uint8_t * pointer) {
for (uint8_t layer = 0; layer < QWIIC_KEYBOARD_LAYERS; layer++) {
for (uint8_t row = 0; row < QWIIC_KEYBOARD_ROWS; row++) {
for (uint8_t col = 0; col < QWIIC_KEYBOARD_COLS; col++) {
uint16_t keycode = pgm_read_word(&keymaps[layer][row][col]);
uint16_t keycode = 0;
keycode = pgm_read_word(&keymaps[layer][row][col]);
*pointer++ = (keycode >> 8);
*pointer++ = (keycode & 0xFF);
}
@ -172,13 +229,13 @@ void qwiic_keyboard_write_keymap(uint8_t * pointer) {
}
}
void qwiic_keyboard_read_keymap(uint8_t * pointer) {
void qwiic_keyboard_read_keymap(uint8_t * pointer, uint8_t index) {
for (uint8_t layer = 0; layer < QWIIC_KEYBOARD_LAYERS; layer++) {
for (uint8_t row = 0; row < QWIIC_KEYBOARD_ROWS; row++) {
for (uint8_t col = 0; col < QWIIC_KEYBOARD_COLS; col++) {
uint16_t keycode = ((*pointer++) << 8);
keycode |= (*pointer++);
qwiic_keyboard_keymap[layer][row][col] = keycode;
qwiic_keyboard_keymap[index][layer][row][col] = keycode;
}
}
}
@ -191,12 +248,11 @@ bool is_keyboard_master(void) {
// overwrite the built-in function
uint16_t keymap_key_to_keycode(uint8_t layer, keypos_t key) {
if (qwiic_keyboard_processing_slave) {
// trick the built-in handling to accept our replacement keymap
return qwiic_keyboard_keymap[(layer)][(key.row)][(key.col)];
//return KC_A;
} else {
if (qwiic_keyboard_processing_slave == QWIIC_KEYBOARD_NOT_PROCESSING) {
// Read entire word (16bits)
return pgm_read_word(&keymaps[(layer)][(key.row)][(key.col)]);
} else {
// trick the built-in handling to accept our replacement keymap
return qwiic_keyboard_keymap[qwiic_keyboard_processing_slave][(layer)][(key.row)][(key.col)];
}
}

@ -141,11 +141,11 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
// 0b1110111 AD <-> VCC
// 0b1110101 AD <-> SCL
// 0b1110110 AD <-> SDA
#define DRIVER_ADDR_1 0b1110100
#define DRIVER_ADDR_2 0b1110110
#define DRIVER_ADDR_1 0b1110111
#define DRIVER_ADDR_2 0b1110101
#define DRIVER_COUNT 2
#define DRIVER_1_LED_TOTAL 25
#define DRIVER_1_LED_TOTAL 24
#define DRIVER_2_LED_TOTAL 24
#define DRIVER_LED_TOTAL DRIVER_1_LED_TOTAL + DRIVER_2_LED_TOTAL

@ -43,73 +43,123 @@ const uint8_t music_map[MATRIX_ROWS][MATRIX_COLS] = LAYOUT_ortho_4x6(
0, 1, 2, 3, 4, 5
);
// const is31_led g_is31_leds[DRIVER_LED_TOTAL] = {
// /* Refer to IS31 manual for these locations
// * driver
// * | R location
// * | | G location
// * | | | B location
// * | | | | */
// {0, C1_3, C2_3, C3_3},
// {0, C1_4, C2_4, C3_4},
// {0, C1_5, C2_5, C3_5},
// {0, C1_11, C2_11, C3_11},
// {0, C1_12, C2_12, C3_12},
// {0, C1_13, C2_13, C3_13},
// {0, C1_6, C2_6, C3_6},
// {0, C1_7, C2_7, C3_7},
// {0, C1_8, C2_8, C3_8},
// {0, C1_14, C2_14, C3_14},
// {0, C1_15, C2_15, C3_15},
// {0, C1_16, C2_16, C3_16},
// {0, C9_1, C8_1, C7_1},
// {0, C9_2, C8_2, C7_2},
// {0, C9_3, C8_3, C7_3},
// {0, C9_9, C8_9, C7_9},
// {0, C9_10, C8_10, C7_10},
// {0, C9_11, C8_11, C7_11},
// {0, C9_4, C8_4, C7_4},
// {0, C9_5, C8_5, C7_5},
// {0, C9_6, C8_6, C7_6},
// {0, C9_12, C8_12, C7_12},
// {0, C9_13, C8_13, C7_13},
// {0, C9_14, C8_14, C7_14}
// };
// const rgb_led g_rgb_leds[DRIVER_LED_TOTAL] = {
// {row | col << 4}
// | {x=0..224, y=0..64}
// | | modifier
// | | |
// {{0|(0<<4)}, {20.36*0, 21.33*0}, 1},
// {{0|(1<<4)}, {20.36*1, 21.33*0}, 0},
// {{0|(2<<4)}, {20.36*2, 21.33*0}, 0},
// {{0|(3<<4)}, {20.36*3, 21.33*0}, 0},
// {{0|(4<<4)}, {20.36*4, 21.33*0}, 0},
// {{0|(5<<4)}, {20.36*5, 21.33*0}, 0},
// {{1|(0<<4)}, {20.36*0, 21.33*1}, 1},
// {{1|(1<<4)}, {20.36*1, 21.33*1}, 0},
// {{1|(2<<4)}, {20.36*2, 21.33*1}, 0},
// {{1|(3<<4)}, {20.36*3, 21.33*1}, 0},
// {{1|(4<<4)}, {20.36*4, 21.33*1}, 0},
// {{1|(5<<4)}, {20.36*5, 21.33*1}, 0},
// {{2|(0<<4)}, {20.36*0, 21.33*2}, 1},
// {{2|(1<<4)}, {20.36*1, 21.33*2}, 0},
// {{2|(2<<4)}, {20.36*2, 21.33*2}, 0},
// {{2|(3<<4)}, {20.36*3, 21.33*2}, 0},
// {{2|(4<<4)}, {20.36*4, 21.33*2}, 0},
// {{2|(5<<4)}, {20.36*5, 21.33*2}, 0},
// {{3|(0<<4)}, {20.36*0, 21.33*3}, 1},
// {{3|(1<<4)}, {20.36*1, 21.33*3}, 1},
// {{3|(2<<4)}, {20.36*2, 21.33*3}, 1},
// {{3|(3<<4)}, {20.36*3, 21.33*3}, 1},
// {{3|(4<<4)}, {20.36*4, 21.33*3}, 1},
// {{3|(5<<4)}, {20.36*5, 21.33*3}, 0}
// };
#ifdef RGB_MATRIX_ENABLE
const is31_led g_is31_leds[DRIVER_LED_TOTAL] = {
/* Refer to IS31 manual for these locations
* driver
* | R location
* | | G location
* | | | B location
* | | | | */
{0, C1_3, C2_3, C3_3},
{0, C1_4, C2_4, C3_4},
{0, C1_5, C2_5, C3_5},
{0, C1_11, C2_11, C3_11},
{0, C1_12, C2_12, C3_12},
{0, C1_13, C2_13, C3_13},
{1, C1_3, C2_3, C3_3},
{1, C1_4, C2_4, C3_4},
{1, C1_5, C2_5, C3_5},
{1, C1_11, C2_11, C3_11},
{1, C1_12, C2_12, C3_12},
{1, C1_13, C2_13, C3_13},
{0, C1_6, C2_6, C3_6},
{0, C1_7, C2_7, C3_7},
{0, C1_8, C2_8, C3_8},
{0, C1_14, C2_14, C3_14},
{0, C1_15, C2_15, C3_15},
{0, C1_16, C2_16, C3_16},
{1, C1_6, C2_6, C3_6},
{1, C1_7, C2_7, C3_7},
{1, C1_8, C2_8, C3_8},
{1, C1_14, C2_14, C3_14},
{1, C1_15, C2_15, C3_15},
{1, C1_16, C2_16, C3_16},
{0, C9_1, C8_1, C7_1},
{0, C9_2, C8_2, C7_2},
{0, C9_3, C8_3, C7_3},
{0, C9_9, C8_9, C7_9},
{0, C9_10, C8_10, C7_10},
{0, C9_11, C8_11, C7_11},
{1, C9_1, C8_1, C7_1},
{1, C9_2, C8_2, C7_2},
{1, C9_3, C8_3, C7_3},
{1, C9_9, C8_9, C7_9},
{1, C9_10, C8_10, C7_10},
{1, C9_11, C8_11, C7_11},
{0, C9_4, C8_4, C7_4},
{0, C9_5, C8_5, C7_5},
{0, C9_6, C8_6, C7_6},
{0, C9_12, C8_12, C7_12},
{0, C9_13, C8_13, C7_13},
{0, C9_14, C8_14, C7_14},
{1, C9_4, C8_4, C7_4},
{1, C9_5, C8_5, C7_5},
{1, C9_6, C8_6, C7_6},
{1, C9_12, C8_12, C7_12},
{1, C9_13, C8_13, C7_13},
{1, C9_14, C8_14, C7_14}
};
const rgb_led g_rgb_leds[DRIVER_LED_TOTAL] = {
/*{row | col << 4}
| {x=0..224, y=0..64}
| | modifier
| | | */
{{0|(0<<4)}, {20.36*0, 21.33*0}, 1},
{{0|(1<<4)}, {20.36*1, 21.33*0}, 0},
{{0|(2<<4)}, {20.36*2, 21.33*0}, 0},
{{0|(3<<4)}, {20.36*3, 21.33*0}, 0},
{{0|(4<<4)}, {20.36*4, 21.33*0}, 0},
{{0|(5<<4)}, {20.36*5, 21.33*0}, 0},
{{0|(6<<4)}, {20.36*6, 21.33*0}, 0},
{{0|(7<<4)}, {20.36*7, 21.33*0}, 0},
{{0|(8<<4)}, {20.36*8, 21.33*0}, 0},
{{0|(9<<4)}, {20.36*9, 21.33*0}, 0},
{{0|(10<<4)}, {20.36*10,21.33*0}, 0},
{{0|(11<<4)}, {20.36*11,21.33*0}, 1},
{{1|(0<<4)}, {20.36*0, 21.33*1}, 1},
{{1|(1<<4)}, {20.36*1, 21.33*1}, 0},
{{1|(2<<4)}, {20.36*2, 21.33*1}, 0},
{{1|(3<<4)}, {20.36*3, 21.33*1}, 0},
{{1|(4<<4)}, {20.36*4, 21.33*1}, 0},
{{1|(5<<4)}, {20.36*5, 21.33*1}, 0},
{{1|(6<<4)}, {20.36*6, 21.33*1}, 0},
{{1|(7<<4)}, {20.36*7, 21.33*1}, 0},
{{1|(8<<4)}, {20.36*8, 21.33*1}, 0},
{{1|(9<<4)}, {20.36*9, 21.33*1}, 0},
{{1|(10<<4)}, {20.36*10,21.33*1}, 0},
{{1|(11<<4)}, {20.36*11,21.33*1}, 1},
{{2|(0<<4)}, {20.36*0, 21.33*2}, 1},
{{2|(1<<4)}, {20.36*1, 21.33*2}, 0},
{{2|(2<<4)}, {20.36*2, 21.33*2}, 0},
{{2|(3<<4)}, {20.36*3, 21.33*2}, 0},
{{2|(4<<4)}, {20.36*4, 21.33*2}, 0},
{{2|(5<<4)}, {20.36*5, 21.33*2}, 0},
{{2|(6<<4)}, {20.36*6, 21.33*2}, 0},
{{2|(7<<4)}, {20.36*7, 21.33*2}, 0},
{{2|(8<<4)}, {20.36*8, 21.33*2}, 0},
{{2|(9<<4)}, {20.36*9, 21.33*2}, 0},
{{2|(10<<4)}, {20.36*10,21.33*2}, 0},
{{2|(11<<4)}, {20.36*11,21.33*2}, 1},
{{3|(0<<4)}, {20.36*0, 21.33*3}, 1},
{{3|(1<<4)}, {20.36*1, 21.33*3}, 1},
{{3|(2<<4)}, {20.36*2, 21.33*3}, 1},
{{3|(3<<4)}, {20.36*3, 21.33*3}, 1},
{{3|(4<<4)}, {20.36*4, 21.33*3}, 1},
{{3|(5<<4)}, {20.36*5, 21.33*3}, 0},
{{3|(6<<4)}, {20.36*6, 21.33*3}, 0},
{{3|(7<<4)}, {20.36*7, 21.33*3}, 1},
{{3|(8<<4)}, {20.36*8, 21.33*3}, 1},
{{3|(9<<4)}, {20.36*9, 21.33*3}, 1},
{{3|(10<<4)}, {20.36*10,21.33*3}, 1},
{{3|(11<<4)}, {20.36*11,21.33*3}, 1}
};
#endif

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