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/*
Copyright 2018 Massdrop Inc.
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/>.
*/
#include "arm_atsam_protocol.h"
#if !defined(MD_BOOTLOADER) && defined(RGB_MATRIX_ENABLE)
# include <string.h>
// From keyboard
# include "config.h"
# include "config_led.h"
# include "matrix.h"
# define I2C_LED_USE_DMA 1 // Set 1 to use background DMA transfers for leds, Set 0 to use inline software transfers
DmacDescriptor dmac_desc;
DmacDescriptor dmac_desc_wb;
static uint8_t i2c_led_q[I2C_Q_SIZE]; // I2C queue circular buffer
static uint8_t i2c_led_q_s; // Start of circular buffer
static uint8_t i2c_led_q_e; // End of circular buffer
static uint8_t i2c_led_q_full; // Queue full counter for reset
static uint8_t dma_sendbuf[I2C_DMA_MAX_SEND]; // Data being written to I2C
volatile uint8_t i2c_led_q_running;
#endif // !defined(MD_BOOTLOADER) && defined(RGB_MATRIX_ENABLE)
void i2c0_init(void) {
DBGC(DC_I2C0_INIT_BEGIN);
CLK_set_i2c0_freq(CHAN_SERCOM_I2C0, FREQ_I2C0_DEFAULT);
// MCU
PORT->Group[0].PMUX[4].bit.PMUXE = 2;
PORT->Group[0].PMUX[4].bit.PMUXO = 2;
PORT->Group[0].PINCFG[8].bit.PMUXEN = 1;
PORT->Group[0].PINCFG[9].bit.PMUXEN = 1;
// I2C
// Note: SW Reset handled in CLK_set_i2c0_freq clks.c
SERCOM0->I2CM.CTRLA.bit.MODE = 5; // Set master mode
SERCOM0->I2CM.CTRLA.bit.SPEED = 0; // Set to 1 for Fast-mode Plus (FM+) up to 1 MHz
SERCOM0->I2CM.CTRLA.bit.RUNSTDBY = 1; // Enabled
SERCOM0->I2CM.CTRLA.bit.ENABLE = 1; // Enable the device
while (SERCOM0->I2CM.SYNCBUSY.bit.ENABLE) {
DBGC(DC_I2C0_INIT_SYNC_ENABLING);
} // Wait for SYNCBUSY.ENABLE to clear
SERCOM0->I2CM.STATUS.bit.BUSSTATE = 1; // Force into IDLE state
while (SERCOM0->I2CM.SYNCBUSY.bit.SYSOP) {
DBGC(DC_I2C0_INIT_SYNC_SYSOP);
}
while (SERCOM0->I2CM.STATUS.bit.BUSSTATE != 1) {
DBGC(DC_I2C0_INIT_WAIT_IDLE);
} // Wait while not idle
DBGC(DC_I2C0_INIT_COMPLETE);
}
uint8_t i2c0_start(uint8_t address) {
SERCOM0->I2CM.ADDR.bit.ADDR = address;
while (SERCOM0->I2CM.SYNCBUSY.bit.SYSOP) {
}
while (SERCOM0->I2CM.INTFLAG.bit.MB == 0) {
}
while (SERCOM0->I2CM.STATUS.bit.RXNACK) {
}
return 1;
}
uint8_t i2c0_transmit(uint8_t address, uint8_t *data, uint16_t length, uint16_t timeout) {
if (!length) return 0;
i2c0_start(address);
while (length) {
SERCOM0->I2CM.DATA.bit.DATA = *data;
while (SERCOM0->I2CM.INTFLAG.bit.MB == 0) {
}
while (SERCOM0->I2CM.STATUS.bit.RXNACK) {
}
data++;
length--;
}
i2c0_stop();
return 1;
}
void i2c0_stop(void) {
if (SERCOM0->I2CM.STATUS.bit.CLKHOLD || SERCOM0->I2CM.INTFLAG.bit.MB == 1 || SERCOM0->I2CM.STATUS.bit.BUSSTATE != 1) {
SERCOM0->I2CM.CTRLB.bit.CMD = 3;
while (SERCOM0->I2CM.SYNCBUSY.bit.SYSOP)
;
while (SERCOM0->I2CM.STATUS.bit.CLKHOLD)
;
while (SERCOM0->I2CM.INTFLAG.bit.MB)
;
while (SERCOM0->I2CM.STATUS.bit.BUSSTATE != 1)
;
}
}
#if !defined(MD_BOOTLOADER) && defined(RGB_MATRIX_ENABLE)
void i2c1_init(void) {
DBGC(DC_I2C1_INIT_BEGIN);
CLK_set_i2c1_freq(CHAN_SERCOM_I2C1, FREQ_I2C1_DEFAULT);
/* MCU */
PORT->Group[0].PMUX[8].bit.PMUXE = 2;
PORT->Group[0].PMUX[8].bit.PMUXO = 2;
PORT->Group[0].PINCFG[16].bit.PMUXEN = 1;
PORT->Group[0].PINCFG[17].bit.PMUXEN = 1;
/* I2C */
// Note: SW Reset handled in CLK_set_i2c1_freq clks.c
SERCOM1->I2CM.CTRLA.bit.MODE = 5; // MODE: Set master mode (No sync)
SERCOM1->I2CM.CTRLA.bit.SPEED = 1; // SPEED: Fm+ up to 1MHz (No sync)
SERCOM1->I2CM.CTRLA.bit.RUNSTDBY = 1; // RUNSTBY: Enabled (No sync)
SERCOM1->I2CM.CTRLB.bit.SMEN = 1; // SMEN: Smart mode enabled (For DMA)(No sync)
NVIC_EnableIRQ(SERCOM1_0_IRQn);
SERCOM1->I2CM.INTENSET.bit.ERROR = 1;
SERCOM1->I2CM.CTRLA.bit.ENABLE = 1; // ENABLE: Enable the device (sync SYNCBUSY.ENABLE)
while (SERCOM1->I2CM.SYNCBUSY.bit.ENABLE) {
DBGC(DC_I2C1_INIT_SYNC_ENABLING);
} // Wait for SYNCBUSY.ENABLE to clear
SERCOM1->I2CM.STATUS.bit.BUSSTATE = 1; // BUSSTATE: Force into IDLE state (sync SYNCBUSY.SYSOP)
while (SERCOM1->I2CM.SYNCBUSY.bit.SYSOP) {
DBGC(DC_I2C1_INIT_SYNC_SYSOP);
}
while (SERCOM1->I2CM.STATUS.bit.BUSSTATE != 1) {
DBGC(DC_I2C1_INIT_WAIT_IDLE);
} // Wait while not idle
DBGC(DC_I2C1_INIT_COMPLETE);
}
uint8_t i2c1_start(uint8_t address) {
SERCOM1->I2CM.ADDR.bit.ADDR = address;
while (SERCOM1->I2CM.SYNCBUSY.bit.SYSOP) {
}
while (SERCOM1->I2CM.INTFLAG.bit.MB == 0) {
}
while (SERCOM1->I2CM.STATUS.bit.RXNACK) {
}
return 1;
}
uint8_t i2c1_transmit(uint8_t address, uint8_t *data, uint16_t length, uint16_t timeout) {
if (!length) return 0;
i2c1_start(address);
while (length) {
SERCOM1->I2CM.DATA.bit.DATA = *data;
while (SERCOM1->I2CM.INTFLAG.bit.MB == 0) {
}
while (SERCOM1->I2CM.STATUS.bit.RXNACK) {
}
data++;
length--;
}
i2c1_stop();
return 1;
}
void i2c1_stop(void) {
if (SERCOM1->I2CM.STATUS.bit.CLKHOLD || SERCOM1->I2CM.INTFLAG.bit.MB == 1 || SERCOM1->I2CM.STATUS.bit.BUSSTATE != 1) {
SERCOM1->I2CM.CTRLB.bit.CMD = 3;
while (SERCOM1->I2CM.SYNCBUSY.bit.SYSOP)
;
while (SERCOM1->I2CM.STATUS.bit.CLKHOLD)
;
while (SERCOM1->I2CM.INTFLAG.bit.MB)
;
while (SERCOM1->I2CM.STATUS.bit.BUSSTATE != 1)
;
}
}
void i2c_led_send_CRWL(uint8_t drvid) {
uint8_t i2cdata[] = {ISSI3733_CMDRWL, ISSI3733_CMDRWL_WRITE_ENABLE_ONCE};
i2c1_transmit(issidrv[drvid].addr, i2cdata, sizeof(i2cdata), 0);
}
void i2c_led_select_page(uint8_t drvid, uint8_t pageno) {
uint8_t i2cdata[] = {ISSI3733_CMDR, pageno};
i2c1_transmit(issidrv[drvid].addr, i2cdata, sizeof(i2cdata), 0);
}
void i2c_led_send_GCR(uint8_t drvid) {
uint8_t i2cdata[] = {ISSI3733_GCCR, 0x00};
if (gcr_actual > LED_GCR_MAX) gcr_actual = LED_GCR_MAX;
i2cdata[1] = gcr_actual;
i2c1_transmit(issidrv[drvid].addr, i2cdata, sizeof(i2cdata), 0);
}
void i2c_led_send_onoff(uint8_t drvid) {
# if I2C_LED_USE_DMA != 1
if (!i2c_led_q_running) {
# endif
i2c_led_send_CRWL(drvid);
i2c_led_select_page(drvid, 0);
# if I2C_LED_USE_DMA != 1
}
# endif
*issidrv[drvid].onoff = 0; // Force start location offset to zero
i2c1_transmit(issidrv[drvid].addr, issidrv[drvid].onoff, ISSI3733_PG0_BYTES, 0);
}
void i2c_led_send_mode_op_gcr(uint8_t drvid, uint8_t mode, uint8_t operation) {
uint8_t i2cdata[] = {ISSI3733_CR, mode | operation, gcr_actual};
i2c1_transmit(issidrv[drvid].addr, i2cdata, sizeof(i2cdata), 0);
}
void i2c_led_send_pur_pdr(uint8_t drvid, uint8_t pur, uint8_t pdr) {
uint8_t i2cdata[] = {ISSI3733_SWYR_PUR, pur, pdr};
i2c1_transmit(issidrv[drvid].addr, i2cdata, sizeof(i2cdata), 0);
}
void i2c_led_send_pwm(uint8_t drvid) {
# if I2C_LED_USE_DMA != 1
if (!i2c_led_q_running) {
# endif
i2c_led_send_CRWL(drvid);
i2c_led_select_page(drvid, 0);
# if I2C_LED_USE_DMA != 1
}
# endif
*issidrv[drvid].pwm = 0; // Force start location offset to zero
i2c1_transmit(issidrv[drvid].addr, issidrv[drvid].pwm, ISSI3733_PG1_BYTES, 0);
}
uint8_t I2C3733_Init_Control(void) {
DBGC(DC_I2C3733_INIT_CONTROL_BEGIN);
// Hardware state shutdown on boot
// USB state machine will enable driver when communication is ready
I2C3733_Control_Set(0);
wait_ms(1);
sr_exp_data.bit.IRST = 0;
SR_EXP_WriteData();
wait_ms(1);
DBGC(DC_I2C3733_INIT_CONTROL_COMPLETE);
return 1;
}
uint8_t I2C3733_Init_Drivers(void) {
DBGC(DC_I2C3733_INIT_DRIVERS_BEGIN);
gcr_actual = ISSI3733_GCR_DEFAULT;
gcr_actual_last = gcr_actual;
if (gcr_actual > LED_GCR_MAX) gcr_actual = LED_GCR_MAX;
gcr_desired = gcr_actual;
// Set up master device
i2c_led_send_CRWL(0);
i2c_led_select_page(0, 3);
i2c_led_send_mode_op_gcr(0, 0, ISSI3733_CR_SSD_NORMAL); // No SYNC due to brightness mismatch with second driver
// Set up slave device
i2c_led_send_CRWL(1);
i2c_led_select_page(1, 3);
i2c_led_send_mode_op_gcr(1, 0, ISSI3733_CR_SSD_NORMAL); // No SYNC due to brightness mismatch with first driver and slight flicker at rgb values 1,2
i2c_led_send_CRWL(0);
i2c_led_select_page(0, 3);
i2c_led_send_pur_pdr(0, ISSI3733_SWYR_PUR_8000, ISSI3733_CSXR_PDR_8000);
i2c_led_send_CRWL(1);
i2c_led_select_page(1, 3);
i2c_led_send_pur_pdr(1, ISSI3733_SWYR_PUR_8000, ISSI3733_CSXR_PDR_8000);
DBGC(DC_I2C3733_INIT_DRIVERS_COMPLETE);
return 1;
}
void I2C_DMAC_LED_Init(void) {
Dmac *dmac = DMAC;
DBGC(DC_I2C_DMAC_LED_INIT_BEGIN);
// Disable device
dmac->CTRL.bit.DMAENABLE = 0; // Disable DMAC
while (dmac->CTRL.bit.DMAENABLE) {
} // Wait for disabled state in case of ongoing transfers
dmac->CTRL.bit.SWRST = 1; // Software Reset DMAC
while (dmac->CTRL.bit.SWRST) {
} // Wait for software reset to complete
// Configure device
dmac->BASEADDR.reg = (uint32_t)&dmac_desc; // Set descriptor base address
dmac->WRBADDR.reg = (uint32_t)&dmac_desc_wb; // Set descriptor write back address
dmac->CTRL.reg |= 0x0f00; // Handle all priorities (LVL0-3)
// Disable channel
dmac->Channel[0].CHCTRLA.bit.ENABLE = 0; // Disable the channel
while (dmac->Channel[0].CHCTRLA.bit.ENABLE) {
} // Wait for disabled state in case of ongoing transfers
dmac->Channel[0].CHCTRLA.bit.SWRST = 1; // Software Reset the channel
while (dmac->Channel[0].CHCTRLA.bit.SWRST) {
} // Wait for software reset to complete
// Configure channel
dmac->Channel[0].CHCTRLA.bit.THRESHOLD = 0; // 1BEAT
dmac->Channel[0].CHCTRLA.bit.BURSTLEN = 0; // SINGLE
dmac->Channel[0].CHCTRLA.bit.TRIGACT = 2; // BURST
dmac->Channel[0].CHCTRLA.bit.TRIGSRC = SERCOM1_DMAC_ID_TX; // Trigger source
dmac->Channel[0].CHCTRLA.bit.RUNSTDBY = 1; // Run in standby
NVIC_EnableIRQ(DMAC_0_IRQn);
dmac->Channel[0].CHINTENSET.bit.TCMPL = 1;
dmac->Channel[0].CHINTENSET.bit.TERR = 1;
// Enable device
dmac->CTRL.bit.DMAENABLE = 1; // Enable DMAC
while (dmac->CTRL.bit.DMAENABLE == 0) {
} // Wait for enable state
DBGC(DC_I2C_DMAC_LED_INIT_COMPLETE);
}
// state = 1 enable
// state = 0 disable
void I2C3733_Control_Set(uint8_t state) {
DBGC(DC_I2C3733_CONTROL_SET_BEGIN);
sr_exp_data.bit.SDB_N = (state == 1 ? 1 : 0);
SR_EXP_WriteData();
DBGC(DC_I2C3733_CONTROL_SET_COMPLETE);
}
void i2c_led_desc_defaults(void) {
dmac_desc.BTCTRL.bit.STEPSIZE = 0; // SRCINC used in favor for auto 1 inc
dmac_desc.BTCTRL.bit.STEPSEL = 0; // SRCINC used in favor for auto 1 inc
dmac_desc.BTCTRL.bit.DSTINC = 0; // The Destination Address Increment is disabled
dmac_desc.BTCTRL.bit.SRCINC = 1; // The Source Address Increment is enabled (Inc by 1)
dmac_desc.BTCTRL.bit.BEATSIZE = 0; // 8-bit bus transfer
dmac_desc.BTCTRL.bit.BLOCKACT = 0; // Channel will be disabled if it is the last block transfer in the transaction
dmac_desc.BTCTRL.bit.EVOSEL = 0; // Event generation disabled
dmac_desc.BTCTRL.bit.VALID = 1; // Set dmac valid
}
void i2c_led_prepare_send_dma(uint8_t *data, uint8_t len) {
i2c_led_desc_defaults();
dmac_desc.BTCNT.reg = len;
dmac_desc.SRCADDR.reg = (uint32_t)data + len;
dmac_desc.DSTADDR.reg = (uint32_t)&SERCOM1->I2CM.DATA.reg;
dmac_desc.DESCADDR.reg = 0;
}
void i2c_led_begin_dma(uint8_t drvid) {
DMAC->Channel[0].CHCTRLA.bit.ENABLE = 1; // Enable the channel
SERCOM1->I2CM.ADDR.reg = (dmac_desc.BTCNT.reg << 16) | 0x2000 | issidrv[drvid].addr; // Begin transfer
}
void i2c_led_send_CRWL_dma(uint8_t drvid) {
*(dma_sendbuf + 0) = ISSI3733_CMDRWL;
*(dma_sendbuf + 1) = ISSI3733_CMDRWL_WRITE_ENABLE_ONCE;
i2c_led_prepare_send_dma(dma_sendbuf, 2);
i2c_led_begin_dma(drvid);
}
void i2c_led_select_page_dma(uint8_t drvid, uint8_t pageno) {
*(dma_sendbuf + 0) = ISSI3733_CMDR;
*(dma_sendbuf + 1) = pageno;
i2c_led_prepare_send_dma(dma_sendbuf, 2);
i2c_led_begin_dma(drvid);
}
void i2c_led_send_GCR_dma(uint8_t drvid) {
*(dma_sendbuf + 0) = ISSI3733_GCCR;
*(dma_sendbuf + 1) = gcr_actual;
i2c_led_prepare_send_dma(dma_sendbuf, 2);
i2c_led_begin_dma(drvid);
}
void i2c_led_send_pwm_dma(uint8_t drvid) {
// Note: This copies the CURRENT pwm buffer, which may be getting modified
memcpy(dma_sendbuf, issidrv[drvid].pwm, ISSI3733_PG1_BYTES);
*dma_sendbuf = 0; // Force start location offset to zero
i2c_led_prepare_send_dma(dma_sendbuf, ISSI3733_PG1_BYTES);
i2c_led_begin_dma(drvid);
}
void i2c_led_send_onoff_dma(uint8_t drvid) {
// Note: This copies the CURRENT onoff buffer, which may be getting modified
memcpy(dma_sendbuf, issidrv[drvid].onoff, ISSI3733_PG0_BYTES);
*dma_sendbuf = 0; // Force start location offset to zero
i2c_led_prepare_send_dma(dma_sendbuf, ISSI3733_PG0_BYTES);
i2c_led_begin_dma(drvid);
}
void i2c_led_q_init(void) {
memset(i2c_led_q, 0, I2C_Q_SIZE);
i2c_led_q_s = 0;
i2c_led_q_e = 0;
i2c_led_q_running = 0;
i2c_led_q_full = 0;
}
uint8_t i2c_led_q_isempty(void) { return i2c_led_q_s == i2c_led_q_e; }
uint8_t i2c_led_q_size(void) { return (i2c_led_q_e - i2c_led_q_s) % I2C_Q_SIZE; }
uint8_t i2c_led_q_available(void) {
return I2C_Q_SIZE - i2c_led_q_size() - 1; // Never allow end to meet start
}
void i2c_led_q_add(uint8_t cmd) {
// WARNING: Always request room before adding commands!
// Assign command
i2c_led_q[i2c_led_q_e] = cmd;
i2c_led_q_e = (i2c_led_q_e + 1) % I2C_Q_SIZE; // Move end up one or wrap
}
void i2c_led_q_s_advance(void) {
i2c_led_q_s = (i2c_led_q_s + 1) % I2C_Q_SIZE; // Move start up one or wrap
}
// Always request room before adding commands
// PS: In case the queue somehow gets filled, it will reset if it can not clear up
// PS: Could only get this to happen through unrealistic timings to overload the I2C bus
uint8_t i2c_led_q_request_room(uint8_t request_size) {
if (request_size > i2c_led_q_available()) {
i2c_led_q_full++;
if (i2c_led_q_full >= 100) // Give the queue a chance to clear up
{
DBG_LED_ON;
I2C_DMAC_LED_Init();
i2c_led_q_init();
return 1;
}
return 0;
}
i2c_led_q_full = 0;
return 1;
}
uint8_t i2c_led_q_run(void) {
if (i2c_led_q_isempty()) {
i2c_led_q_running = 0;
return 0;
}
if (i2c_led_q_running) return 1;
i2c_led_q_running = 1;
# if I2C_LED_USE_DMA != 1
while (!i2c_led_q_isempty()) {
# endif
// run command
if (i2c_led_q[i2c_led_q_s] == I2C_Q_CRWL) {
i2c_led_q_s_advance();
uint8_t drvid = i2c_led_q[i2c_led_q_s];
# if I2C_LED_USE_DMA == 1
i2c_led_send_CRWL_dma(drvid);
# else
i2c_led_send_CRWL(drvid);
# endif
} else if (i2c_led_q[i2c_led_q_s] == I2C_Q_PAGE_SELECT) {
i2c_led_q_s_advance();
uint8_t drvid = i2c_led_q[i2c_led_q_s];
i2c_led_q_s_advance();
uint8_t page = i2c_led_q[i2c_led_q_s];
# if I2C_LED_USE_DMA == 1
i2c_led_select_page_dma(drvid, page);
# else
i2c_led_select_page(drvid, page);
# endif
} else if (i2c_led_q[i2c_led_q_s] == I2C_Q_PWM) {
i2c_led_q_s_advance();
uint8_t drvid = i2c_led_q[i2c_led_q_s];
# if I2C_LED_USE_DMA == 1
i2c_led_send_pwm_dma(drvid);
# else
i2c_led_send_pwm(drvid);
# endif
} else if (i2c_led_q[i2c_led_q_s] == I2C_Q_GCR) {
i2c_led_q_s_advance();
uint8_t drvid = i2c_led_q[i2c_led_q_s];
# if I2C_LED_USE_DMA == 1
i2c_led_send_GCR_dma(drvid);
# else
i2c_led_send_GCR(drvid);
# endif
} else if (i2c_led_q[i2c_led_q_s] == I2C_Q_ONOFF) {
i2c_led_q_s_advance();
uint8_t drvid = i2c_led_q[i2c_led_q_s];
# if I2C_LED_USE_DMA == 1
i2c_led_send_onoff_dma(drvid);
# else
i2c_led_send_onoff(drvid);
# endif
}
i2c_led_q_s_advance(); // Advance last run command or if the command byte was not serviced
# if I2C_LED_USE_DMA != 1
}
i2c_led_q_running = 0;
# endif
return 1;
}
__attribute__((weak)) void i2c_init(void) {
static bool is_initialised = false;
if (!is_initialised) {
is_initialised = true;
i2c0_init();
}
}
i2c_status_t i2c_transmit(uint8_t address, const uint8_t *data, uint16_t length, uint16_t timeout) {
uint8_t ret = i2c0_transmit(address, (uint8_t *)data, length, timeout);
SERCOM0->I2CM.CTRLB.bit.CMD = 0x03;
while (SERCOM0->I2CM.SYNCBUSY.bit.SYSOP) {
DBGC(DC_USB_WRITE2422_BLOCK_SYNC_SYSOP);
}
return ret ? I2C_STATUS_SUCCESS : I2C_STATUS_ERROR;
}
#endif // !defined(MD_BOOTLOADER) && defined(RGB_MATRIX_ENABLE)
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