qmk/drivers/issi/is31fl3736.c
Wilba6582 13e166d9c4 RAMA U80-A, wilba.tech WT60-A, WT65-A, WT80-A, IS31FL3736 driver (#3925)
* Initial commit of RAMA U80-A

* Initial commit of RAMA U80-A

* Moved IS31FL3736 driver, minor cleanups

* Superficial stuff

* Review changes

* Refactored to use common code.
2018-09-27 10:40:44 -04:00

307 lines
9.7 KiB
C

/* Copyright 2018 Jason Williams (Wilba)
*
* 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/>.
*/
#ifdef __AVR__
#include <avr/interrupt.h>
#include <avr/io.h>
#include <util/delay.h>
#else
#include "wait.h"
#endif
#include "is31fl3736.h"
#include <string.h>
#include "i2c_master.h"
#include "progmem.h"
// This is a 7-bit address, that gets left-shifted and bit 0
// set to 0 for write, 1 for read (as per I2C protocol)
// The address will vary depending on your wiring:
// 00 <-> GND
// 01 <-> SCL
// 10 <-> SDA
// 11 <-> VCC
// ADDR1 represents A1:A0 of the 7-bit address.
// ADDR2 represents A3:A2 of the 7-bit address.
// The result is: 0b101(ADDR2)(ADDR1)
#define ISSI_ADDR_DEFAULT 0x50
#define ISSI_COMMANDREGISTER 0xFD
#define ISSI_COMMANDREGISTER_WRITELOCK 0xFE
#define ISSI_INTERRUPTMASKREGISTER 0xF0
#define ISSI_INTERRUPTSTATUSREGISTER 0xF1
#define ISSI_PAGE_LEDCONTROL 0x00 //PG0
#define ISSI_PAGE_PWM 0x01 //PG1
#define ISSI_PAGE_AUTOBREATH 0x02 //PG2
#define ISSI_PAGE_FUNCTION 0x03 //PG3
#define ISSI_REG_CONFIGURATION 0x00 //PG3
#define ISSI_REG_GLOBALCURRENT 0x01 //PG3
#define ISSI_REG_RESET 0x11// PG3
#define ISSI_REG_SWPULLUP 0x0F //PG3
#define ISSI_REG_CSPULLUP 0x10 //PG3
#ifndef ISSI_TIMEOUT
#define ISSI_TIMEOUT 100
#endif
#ifndef ISSI_PERSISTENCE
#define ISSI_PERSISTENCE 0
#endif
// Transfer buffer for TWITransmitData()
uint8_t g_twi_transfer_buffer[20];
// These buffers match the IS31FL3736 PWM registers.
// The control buffers match the PG0 LED On/Off registers.
// Storing them like this is optimal for I2C transfers to the registers.
// We could optimize this and take out the unused registers from these
// buffers and the transfers in IS31FL3736_write_pwm_buffer() but it's
// probably not worth the extra complexity.
uint8_t g_pwm_buffer[DRIVER_COUNT][192];
bool g_pwm_buffer_update_required = false;
uint8_t g_led_control_registers[DRIVER_COUNT][24] = { { 0 }, { 0 } };
bool g_led_control_registers_update_required = false;
void IS31FL3736_write_register( uint8_t addr, uint8_t reg, uint8_t data )
{
g_twi_transfer_buffer[0] = reg;
g_twi_transfer_buffer[1] = data;
#if ISSI_PERSISTENCE > 0
for (uint8_t i = 0; i < ISSI_PERSISTENCE; i++) {
if (i2c_transmit(addr << 1, g_twi_transfer_buffer, 2, ISSI_TIMEOUT) == 0)
break;
}
#else
i2c_transmit(addr << 1, g_twi_transfer_buffer, 2, ISSI_TIMEOUT);
#endif
}
void IS31FL3736_write_pwm_buffer( uint8_t addr, uint8_t *pwm_buffer )
{
// assumes PG1 is already selected
// transmit PWM registers in 12 transfers of 16 bytes
// g_twi_transfer_buffer[] is 20 bytes
// iterate over the pwm_buffer contents at 16 byte intervals
for ( int i = 0; i < 192; i += 16 ) {
g_twi_transfer_buffer[0] = i;
// copy the data from i to i+15
// device will auto-increment register for data after the first byte
// thus this sets registers 0x00-0x0F, 0x10-0x1F, etc. in one transfer
for ( int j = 0; j < 16; j++ ) {
g_twi_transfer_buffer[1 + j] = pwm_buffer[i + j];
}
#if ISSI_PERSISTENCE > 0
for (uint8_t i = 0; i < ISSI_PERSISTENCE; i++) {
if (i2c_transmit(addr << 1, g_twi_transfer_buffer, 17, ISSI_TIMEOUT) == 0)
break;
}
#else
i2c_transmit(addr << 1, g_twi_transfer_buffer, 17, ISSI_TIMEOUT);
#endif
}
}
void IS31FL3736_init( uint8_t addr )
{
// In order to avoid the LEDs being driven with garbage data
// in the LED driver's PWM registers, shutdown is enabled last.
// Set up the mode and other settings, clear the PWM registers,
// then disable software shutdown.
// Unlock the command register.
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER_WRITELOCK, 0xC5 );
// Select PG0
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER, ISSI_PAGE_LEDCONTROL );
// Turn off all LEDs.
for ( int i = 0x00; i <= 0x17; i++ )
{
IS31FL3736_write_register( addr, i, 0x00 );
}
// Unlock the command register.
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER_WRITELOCK, 0xC5 );
// Select PG1
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER, ISSI_PAGE_PWM );
// Set PWM on all LEDs to 0
// No need to setup Breath registers to PWM as that is the default.
for ( int i = 0x00; i <= 0xBF; i++ )
{
IS31FL3736_write_register( addr, i, 0x00 );
}
// Unlock the command register.
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER_WRITELOCK, 0xC5 );
// Select PG3
IS31FL3736_write_register( addr, ISSI_COMMANDREGISTER, ISSI_PAGE_FUNCTION );
// Set global current to maximum.
IS31FL3736_write_register( addr, ISSI_REG_GLOBALCURRENT, 0xFF );
// Disable software shutdown.
IS31FL3736_write_register( addr, ISSI_REG_CONFIGURATION, 0x01 );
// Wait 10ms to ensure the device has woken up.
#ifdef __AVR__
_delay_ms( 10 );
#else
wait_ms(10);
#endif
}
void IS31FL3736_set_color( int index, uint8_t red, uint8_t green, uint8_t blue )
{
if ( index >= 0 && index < DRIVER_LED_TOTAL ) {
is31_led led = g_is31_leds[index];
g_pwm_buffer[led.driver][led.r] = red;
g_pwm_buffer[led.driver][led.g] = green;
g_pwm_buffer[led.driver][led.b] = blue;
g_pwm_buffer_update_required = true;
}
}
void IS31FL3736_set_color_all( uint8_t red, uint8_t green, uint8_t blue )
{
for ( int i = 0; i < DRIVER_LED_TOTAL; i++ )
{
IS31FL3736_set_color( i, red, green, blue );
}
}
void IS31FL3736_set_led_control_register( uint8_t index, bool red, bool green, bool blue )
{
is31_led led = g_is31_leds[index];
// IS31FL3733
// The PWM register for a matrix position (0x00 to 0xBF) can be
// divided by 8 to get the LED control register (0x00 to 0x17),
// then mod 8 to get the bit position within that register.
// IS31FL3736
// The PWM register for a matrix position (0x00 to 0xBF) is interleaved, so:
// A1=0x00 A2=0x02 A3=0x04 A4=0x06 A5=0x08 A6=0x0A A7=0x0C A8=0x0E
// B1=0x10 B2=0x12 B3=0x14
// But also, the LED control registers (0x00 to 0x17) are also interleaved, so:
// A1-A4=0x00 A5-A8=0x01
// So, the same math applies.
uint8_t control_register_r = led.r / 8;
uint8_t control_register_g = led.g / 8;
uint8_t control_register_b = led.b / 8;
uint8_t bit_r = led.r % 8;
uint8_t bit_g = led.g % 8;
uint8_t bit_b = led.b % 8;
if ( red ) {
g_led_control_registers[led.driver][control_register_r] |= (1 << bit_r);
} else {
g_led_control_registers[led.driver][control_register_r] &= ~(1 << bit_r);
}
if ( green ) {
g_led_control_registers[led.driver][control_register_g] |= (1 << bit_g);
} else {
g_led_control_registers[led.driver][control_register_g] &= ~(1 << bit_g);
}
if ( blue ) {
g_led_control_registers[led.driver][control_register_b] |= (1 << bit_b);
} else {
g_led_control_registers[led.driver][control_register_b] &= ~(1 << bit_b);
}
g_led_control_registers_update_required = true;
}
void IS31FL3736_mono_set_brightness( int index, uint8_t value )
{
if ( index >= 0 && index < 96 ) {
// Index in range 0..95 -> A1..A8, B1..B8, etc.
// Map index 0..95 to registers 0x00..0xBE (interleaved)
uint8_t pwm_register = index * 2;
g_pwm_buffer[0][pwm_register] = value;
g_pwm_buffer_update_required = true;
}
}
void IS31FL3736_mono_set_brightness_all( uint8_t value )
{
for ( int i = 0; i < 96; i++ )
{
IS31FL3736_mono_set_brightness( i, value );
}
}
void IS31FL3736_mono_set_led_control_register( uint8_t index, bool enabled )
{
// Index in range 0..95 -> A1..A8, B1..B8, etc.
// Map index 0..95 to registers 0x00..0xBE (interleaved)
uint8_t pwm_register = index * 2;
// Map register 0x00..0xBE (interleaved) into control register and bit
uint8_t control_register = pwm_register / 8;
uint8_t bit = pwm_register % 8;
if ( enabled ) {
g_led_control_registers[0][control_register] |= (1 << bit);
} else {
g_led_control_registers[0][control_register] &= ~(1 << bit);
}
g_led_control_registers_update_required = true;
}
void IS31FL3736_update_pwm_buffers( uint8_t addr1, uint8_t addr2 )
{
if ( g_pwm_buffer_update_required )
{
// Firstly we need to unlock the command register and select PG1
IS31FL3736_write_register( addr1, ISSI_COMMANDREGISTER_WRITELOCK, 0xC5 );
IS31FL3736_write_register( addr1, ISSI_COMMANDREGISTER, ISSI_PAGE_PWM );
IS31FL3736_write_pwm_buffer( addr1, g_pwm_buffer[0] );
//IS31FL3736_write_pwm_buffer( addr2, g_pwm_buffer[1] );
}
g_pwm_buffer_update_required = false;
}
void IS31FL3736_update_led_control_registers( uint8_t addr1, uint8_t addr2 )
{
if ( g_led_control_registers_update_required )
{
// Firstly we need to unlock the command register and select PG0
IS31FL3736_write_register( addr1, ISSI_COMMANDREGISTER_WRITELOCK, 0xC5 );
IS31FL3736_write_register( addr1, ISSI_COMMANDREGISTER, ISSI_PAGE_LEDCONTROL );
for ( int i=0; i<24; i++ )
{
IS31FL3736_write_register(addr1, i, g_led_control_registers[0][i] );
//IS31FL3736_write_register(addr2, i, g_led_control_registers[1][i] );
}
}
}