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qmk_firmware/keyboards/infinity60/led_controller.c

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/*
Copyright 2016 flabbergast <s3+flabbergast@sdfeu.org>
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/*
* LED controller code
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* IS31FL3731C matrix LED driver from ISSI
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* datasheet: http://www.issi.com/WW/pdf/31FL3731C.pdf
*/
#include "ch.h"
#include "hal.h"
#include "print.h"
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#include "led.h"
#include "host.h"
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#include "led_controller.h"
#include "suspend.h"
#include "usb_main.h"
/* Infinity60 LED MAP
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- digits mean "row" and "col", i.e. 45 means C4-5 in the IS31 datasheet, matrix A
11 12 13 14 15 16 17 18 21 22 23 24 25 26 27*
28 31 32 33 34 35 36 37 38 41 42 43 44 45
46 47 48 51 52 53 54 55 56 57 58 61 62
63 64 65 66 67 68 71 72 73 74 75 76 77*
78 81 82 83 84 85 86 87
*Unused in Alphabet Layout
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*/
/*
each page has 0xB4 bytes
0 - 0x11: LED control (on/off):
order: CA1, CB1, CA2, CB2, .... (CA - matrix A, CB - matrix B)
CAn controls Cn-8 .. Cn-1 (LSbit)
0x12 - 0x23: blink control (like "LED control")
0x24 - 0xB3: PWM control: byte per LED, 0xFF max on
order same as above (CA 1st row (8bytes), CB 1st row (8bytes), ...)
*/
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// Which LED should be used for CAPS LOCK indicator
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#if !defined(CAPS_LOCK_LED_ADDRESS)
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#define CAPS_LOCK_LED_ADDRESS 46
#endif
#if !defined(NUM_LOCK_LED_ADDRESS)
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#define NUM_LOCK_LED_ADDRESS 85
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#endif
/* Which LED should breathe during sleep */
#if !defined(BREATHE_LED_ADDRESS)
#define BREATHE_LED_ADDRESS CAPS_LOCK_LED_ADDRESS
#endif
/* =================
* ChibiOS I2C setup
* ================= */
static const I2CConfig i2ccfg = {
400000 // clock speed (Hz); 400kHz max for IS31
};
/* ==============
* variables
* ============== */
// internal communication buffers
uint8_t tx[2] __attribute__((aligned(2)));
uint8_t rx[1] __attribute__((aligned(2)));
// buffer for sending the whole page at once (used also as a temp buffer)
uint8_t full_page[0xB4+1] = {0};
// LED mask (which LEDs are present, selected by bits)
// IC60 pcb uses only CA matrix.
// Each byte is a control pin for 8 leds ordered 8-1
const uint8_t all_on_leds_mask[0x12] = {
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0xFF, 0x00, 0xFF, 0x00, 0xFF, 0x00, 0xFF, 0x00, 0xFF,
0x00, 0xFF, 0x00, 0xFF, 0x00, 0x7F, 0x00, 0x00, 0x00
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};
// array to hold brightness pwm steps
const uint8_t pwm_levels[5] = {
0x00, 0x16, 0x4E, 0xA1, 0xFF
};
// array to write to pwm register
uint8_t pwm_register_array[9] = {0};
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/* ============================
* communication functions
* ============================ */
msg_t is31_select_page(uint8_t page) {
tx[0] = IS31_COMMANDREGISTER;
tx[1] = page;
return i2cMasterTransmitTimeout(&I2CD1, IS31_ADDR_DEFAULT, tx, 2, NULL, 0, US2ST(IS31_TIMEOUT));
}
msg_t is31_write_data(uint8_t page, uint8_t *buffer, uint8_t size) {
is31_select_page(page);
return i2cMasterTransmitTimeout(&I2CD1, IS31_ADDR_DEFAULT, buffer, size, NULL, 0, US2ST(IS31_TIMEOUT));
}
msg_t is31_write_register(uint8_t page, uint8_t reg, uint8_t data) {
is31_select_page(page);
tx[0] = reg;
tx[1] = data;
return i2cMasterTransmitTimeout(&I2CD1, IS31_ADDR_DEFAULT, tx, 2, NULL, 0, US2ST(IS31_TIMEOUT));
}
msg_t is31_read_register(uint8_t page, uint8_t reg, uint8_t *result) {
is31_select_page(page);
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tx[0] = reg;
return i2cMasterTransmitTimeout(&I2CD1, IS31_ADDR_DEFAULT, tx, 1, result, 1, US2ST(IS31_TIMEOUT));
}
/* ========================
* initialise the IS31 chip
* ======================== */
void is31_init(void) {
// just to be sure that it's all zeroes
__builtin_memset(full_page,0,0xB4+1);
// zero function page, all registers (assuming full_page is all zeroes)
is31_write_data(IS31_FUNCTIONREG, full_page, 0xD + 1);
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// disable hardware shutdown
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palSetPadMode(GPIOB, 16, PAL_MODE_OUTPUT_PUSHPULL);
palSetPad(GPIOB, 16);
chThdSleepMilliseconds(10);
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// software shutdown
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_ON);
chThdSleepMilliseconds(10);
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// zero function page, all registers
is31_write_data(IS31_FUNCTIONREG, full_page, 0xD + 1);
chThdSleepMilliseconds(10);
// software shutdown disable (i.e. turn stuff on)
is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_OFF);
chThdSleepMilliseconds(10);
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// zero all LED registers on all 8 pages
uint8_t i;
for(i=0; i<8; i++) {
is31_write_data(i, full_page, 0xB4 + 1);
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chThdSleepMilliseconds(5);
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}
}
/* ==================
* LED control thread
* ================== */
#define LED_MAILBOX_NUM_MSGS 5
static msg_t led_mailbox_queue[LED_MAILBOX_NUM_MSGS];
mailbox_t led_mailbox;
static THD_WORKING_AREA(waLEDthread, 256);
static THD_FUNCTION(LEDthread, arg) {
(void)arg;
chRegSetThreadName("LEDthread");
uint8_t i;
uint8_t control_register_word[2] = {0};//2 bytes: register address, byte to write
uint8_t led_control_reg[0x13] = {0};//led control register start address + 0x12 bytes
//persistent status variables
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uint8_t pwm_step_status, page_status, capslock_status, numlock_status;
//mailbox variables
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uint8_t temp, msg_type;
uint8_t msg_args[3];
msg_t msg;
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// initialize persistent variables
pwm_step_status = 4; //full brightness
page_status = 0; //start frame 0 (all off/on)
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numlock_status = (host_keyboard_leds() & (1<<USB_LED_NUM_LOCK)) ? 1 : 0;
capslock_status = (host_keyboard_leds() & (1<<USB_LED_CAPS_LOCK)) ? 1 : 0;
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while(true) {
// wait for a message (asynchronous)
// (messages are queued (up to LED_MAILBOX_NUM_MSGS) if they can't
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// be processed right away
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chMBFetch(&led_mailbox, &msg, TIME_INFINITE);
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msg_type = msg & 0xFF; //first byte is action information
msg_args[0] = (msg >> 8) & 0xFF;
msg_args[1] = (msg >> 16) & 0XFF;
msg_args[2] = (msg >> 24) & 0xFF;
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switch (msg_type){
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case SET_FULL_ROW:
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//write full byte to pin address, msg_args[1] = pin #, msg_args[0] = 8 bits to write
//writes only to currently displayed page
write_led_byte(page_status, msg_args[1], msg_args[0]);
break;
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case OFF_LED:
//on/off/toggle single led, msg_args[0] = row/col of led, msg_args[1] = page
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set_led_bit(msg_args[1], control_register_word, msg_args[0], 0);
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break;
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case ON_LED:
set_led_bit(msg_args[1], control_register_word, msg_args[0], 1);
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break;
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case TOGGLE_LED:
set_led_bit(msg_args[1], control_register_word, msg_args[0], 2);
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break;
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case BLINK_OFF_LED:
//on/off/toggle single led, msg_args[0] = row/col of led
set_led_bit(msg_args[1], control_register_word, msg_args[0], 4);
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break;
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case BLINK_ON_LED:
set_led_bit(msg_args[1], control_register_word, msg_args[0], 5);
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break;
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case BLINK_TOGGLE_LED:
set_led_bit(msg_args[1], control_register_word, msg_args[0], 6);
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break;
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case TOGGLE_ALL:
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//turn on/off all leds, msg_args = unused
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_ON);
chThdSleepMilliseconds(5);
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is31_read_register(0, 0x00, &temp);
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_OFF);
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led_control_reg[0] = 0;
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//toggle led mask based on current state (temp)
if (temp==0 || page_status > 0) {
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__builtin_memcpy(led_control_reg+1, all_on_leds_mask, 0x12);
} else {
__builtin_memset(led_control_reg+1, 0, 0x12);
}
is31_write_data(0, led_control_reg, 0x13);
if (page_status > 0) {
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_PICTDISP, 0);
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page_status=0;
//maintain lock leds, reset to off and force recheck to blink of all leds toggled on
numlock_status = 0;
capslock_status = 0;
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led_set(host_keyboard_leds());
}
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break;
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case TOGGLE_BACKLIGHT:
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//msg_args[0] = on/off
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//populate 9 byte rows to be written to each pin, first byte is register (pin) address
if (msg_args[0] == 1) {
__builtin_memset(pwm_register_array+1, pwm_levels[pwm_step_status], 8);
} else {
__builtin_memset(pwm_register_array+1, 0, 8);
}
for(i=0; i<8; i++) {
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//first byte is register address, every 0x10 9 bytes is A-matrix pwm pins
pwm_register_array[0] = 0x24 + (i * 0x10);
is31_write_data(0,pwm_register_array,9);
}
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break;
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case DISPLAY_PAGE:
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//msg_args[0] = page to toggle on
if (page_status != msg_args[0]) {
is31_write_register(IS31_FUNCTIONREG, IS31_REG_PICTDISP, msg_args[0]);
page_status = msg_args[0];
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//maintain lock leds, reset to off and force recheck for new page
numlock_status = 0;
capslock_status = 0;
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led_set(host_keyboard_leds());
}
break;
case RESET_PAGE:
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//led_args[0] = page to reset
led_control_reg[0] = 0;
__builtin_memset(led_control_reg+1, 0, 0x12);
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is31_write_data(msg_args[0], led_control_reg, 0x13);
//repeat for blink register
led_control_reg[0] = 0x12;
is31_write_data(msg_args[0], led_control_reg, 0x13);
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break;
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case TOGGLE_NUM_LOCK:
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//msg_args[0] = 0 or 1, off/on
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if (numlock_status != msg_args[0]) {
set_lock_leds(NUM_LOCK_LED_ADDRESS, msg_args[0], page_status);
numlock_status = msg_args[0];
}
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break;
case TOGGLE_CAPS_LOCK:
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//msg_args[0] = 0 or 1, off/on
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if (capslock_status != msg_args[0]) {
set_lock_leds(CAPS_LOCK_LED_ADDRESS, msg_args[0], page_status);
capslock_status = msg_args[0];
}
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break;
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case STEP_BRIGHTNESS:
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//led_args[0] = step up (1) or down (0)
switch (msg_args[0]) {
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case 0:
if (pwm_step_status == 0) {
pwm_step_status = 4;
} else {
pwm_step_status--;
}
break;
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case 1:
if (pwm_step_status == 4) {
pwm_step_status = 0;
} else {
pwm_step_status++;
}
break;
}
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//populate 8 byte arrays to write on each pin
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//first byte is register address, every 0x10 9 bytes are A-matrix pwm pins
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__builtin_memset(pwm_register_array+1, pwm_levels[pwm_step_status], 8);
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for(i=0; i<8; i++) {
pwm_register_array[0] = 0x24 + (i * 0x10);
is31_write_data(0,pwm_register_array,9);
}
break;
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}
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}
}
/* ==============================
* led processing functions
* ============================== */
void set_led_bit (uint8_t page, uint8_t *led_control_word, uint8_t led_addr, uint8_t action) {
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//returns 2 bytes: led control register address and byte to write
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//action: 0 - off, 1 - on, 2 - toggle, 4 - blink on, 5 - blink off, 6 - toggle blink
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uint8_t control_reg_addr, column_bit, column_byte, temp, blink_bit;
//check for valid led address
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if (led_addr < 0 || led_addr > 87 || led_addr % 10 > 8) {
return;
}
blink_bit = action>>2;//check for blink bit
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action &= ~(1<<2); //strip blink bit
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//led_addr tens column is pin#, ones column is bit position in 8-bit mask
control_reg_addr = ((led_addr / 10) % 10 - 1 ) * 0x02;// A-matrix is every other byte
control_reg_addr += blink_bit == 1 ? 0x12 : 0x00;//if blink_bit, shift 12 bytes to blink register
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_ON);
chThdSleepMilliseconds(5);
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is31_read_register(page, control_reg_addr, &temp);//maintain status of leds on this byte
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_OFF);
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column_bit = 1<<(led_addr % 10 - 1);
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column_byte = temp;
switch(action) {
case 0:
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column_byte &= ~column_bit;
break;
case 1:
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column_byte |= column_bit;
break;
case 2:
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column_byte ^= column_bit;
break;
}
//return word to be written in register
led_control_word[0] = control_reg_addr;
led_control_word[1] = column_byte;
is31_write_data (page, led_control_word, 0x02);
}
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void write_led_byte (uint8_t page, uint8_t row, uint8_t led_byte) {
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uint8_t led_control_word[2] = {0};//register address and on/off byte
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led_control_word[0] = (row - 1 ) * 0x02;// A-matrix is every other byte
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led_control_word[1] = led_byte;
is31_write_data(page, led_control_word, 0x02);
}
void write_led_page (uint8_t page, uint8_t *user_led_array, uint8_t led_count) {
uint8_t i;
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uint8_t pin, col;
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uint8_t led_control_register[0x13] = {0};
__builtin_memset(led_control_register,0,13);
for(i=0;i<led_count;i++){
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//shift pin by 1 for led register 0x00 address
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pin = ((user_led_array[i] / 10) % 10 - 1 ) * 2 + 1;
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col = user_led_array[i] % 10 - 1;
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led_control_register[pin] |= 1<<(col);
}
is31_write_data(page, led_control_register, 0x13);
}
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void set_lock_leds(uint8_t led_addr, uint8_t led_action, uint8_t page) {
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uint8_t temp;
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uint8_t led_control_word[2] = {0};
//blink if all leds are on
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if (page == 0) {
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_ON);
chThdSleepMilliseconds(5);
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is31_read_register(0, 0x00, &temp);
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_SHUTDOWN, IS31_REG_SHUTDOWN_OFF);
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if (temp == 0xFF) {
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led_action |= (1<<2); //set blink bit
}
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}
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set_led_bit(page,led_control_word,led_addr,led_action);
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}
/* =====================
* hook into user keymap
* ===================== */
void led_controller_init(void) {
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uint8_t i;
/* initialise I2C */
/* I2C pins */
palSetPadMode(GPIOB, 0, PAL_MODE_ALTERNATIVE_2); // PTB0/I2C0/SCL
palSetPadMode(GPIOB, 1, PAL_MODE_ALTERNATIVE_2); // PTB1/I2C0/SDA
/* start I2C */
i2cStart(&I2CD1, &i2ccfg);
// try high drive (from kiibohd)
I2CD1.i2c->C2 |= I2Cx_C2_HDRS;
// try glitch fixing (from kiibohd)
I2CD1.i2c->FLT = 4;
chThdSleepMilliseconds(10);
/* initialise IS31 chip */
is31_init();
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//set Display Option Register so all pwm intensity is controlled from page 0
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//enable blink and set blink period to 0.27s x rate
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is31_write_register(IS31_FUNCTIONREG, IS31_REG_DISPLAYOPT, IS31_REG_DISPLAYOPT_INTENSITY_SAME + IS31_REG_DISPLAYOPT_BLINK_ENABLE + 4);
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/* set full pwm on page 1 */
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pwm_register_array[0] = 0;
__builtin_memset(pwm_register_array+1, 0xFF, 8);
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for(i=0; i<8; i++) {
pwm_register_array[0] = 0x24 + (i * 0x10);//first byte of 9 bytes must be register address
is31_write_data(0, pwm_register_array, 9);
chThdSleepMilliseconds(5);
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}
/* enable breathing when the displayed page changes */
// Fade-in Fade-out, time = 26ms * 2^N, N=3
is31_write_register(IS31_FUNCTIONREG, IS31_REG_BREATHCTRL1, (3<<4)|3);
is31_write_register(IS31_FUNCTIONREG, IS31_REG_BREATHCTRL2, IS31_REG_BREATHCTRL2_ENABLE|3);
/* more time consuming LED processing should be offloaded into
* a thread, with asynchronous messaging. */
chMBObjectInit(&led_mailbox, led_mailbox_queue, LED_MAILBOX_NUM_MSGS);
chThdCreateStatic(waLEDthread, sizeof(waLEDthread), LOWPRIO, LEDthread, NULL);
}