mh
/
qmk_firmware
mirror of https://github.com/qmk/qmk_firmware/


								/* Copyright 2020 Christopher Courtney, aka Drashna Jael're  (@drashna) <drashna@live.com>

								 * Copyright 2019 Sunjun Kim

								 * Copyright 2020 Ploopy Corporation

								 *

								 * 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 "pmw3360.h"

								#include "wait.h"

								#include "debug.h"

								#include "print.h"

								#include "pmw3360_firmware.h"


								// Registers

								#define REG_Product_ID                 0x00

								#define REG_Revision_ID                0x01

								#define REG_Motion                     0x02

								#define REG_Delta_X_L                  0x03

								#define REG_Delta_X_H                  0x04

								#define REG_Delta_Y_L                  0x05

								#define REG_Delta_Y_H                  0x06

								#define REG_SQUAL                      0x07

								#define REG_Raw_Data_Sum               0x08

								#define REG_Maximum_Raw_data           0x09

								#define REG_Minimum_Raw_data           0x0A

								#define REG_Shutter_Lower              0x0B

								#define REG_Shutter_Upper              0x0C

								#define REG_Control                    0x0D

								#define REG_Config1                    0x0F

								#define REG_Config2                    0x10

								#define REG_Angle_Tune                 0x11

								#define REG_Frame_Capture              0x12

								#define REG_SROM_Enable                0x13

								#define REG_Run_Downshift              0x14

								#define REG_Rest1_Rate_Lower           0x15

								#define REG_Rest1_Rate_Upper           0x16

								#define REG_Rest1_Downshift            0x17

								#define REG_Rest2_Rate_Lower           0x18

								#define REG_Rest2_Rate_Upper           0x19

								#define REG_Rest2_Downshift            0x1A

								#define REG_Rest3_Rate_Lower           0x1B

								#define REG_Rest3_Rate_Upper           0x1C

								#define REG_Observation                0x24

								#define REG_Data_Out_Lower             0x25

								#define REG_Data_Out_Upper             0x26

								#define REG_Raw_Data_Dump              0x29

								#define REG_SROM_ID                    0x2A

								#define REG_Min_SQ_Run                 0x2B

								#define REG_Raw_Data_Threshold         0x2C

								#define REG_Config5                    0x2F

								#define REG_Power_Up_Reset             0x3A

								#define REG_Shutdown                   0x3B

								#define REG_Inverse_Product_ID         0x3F

								#define REG_LiftCutoff_Tune3           0x41

								#define REG_Angle_Snap                 0x42

								#define REG_LiftCutoff_Tune1           0x4A

								#define REG_Motion_Burst               0x50

								#define REG_LiftCutoff_Tune_Timeout    0x58

								#define REG_LiftCutoff_Tune_Min_Length 0x5A

								#define REG_SROM_Load_Burst            0x62

								#define REG_Lift_Config                0x63

								#define REG_Raw_Data_Burst             0x64

								#define REG_LiftCutoff_Tune2           0x65


								bool _inBurst = false;


								void print_byte(uint8_t byte) { dprintf("%c%c%c%c%c%c%c%c|", (byte & 0x80 ? '1' : '0'), (byte & 0x40 ? '1' : '0'), (byte & 0x20 ? '1' : '0'), (byte & 0x10 ? '1' : '0'), (byte & 0x08 ? '1' : '0'), (byte & 0x04 ? '1' : '0'), (byte & 0x02 ? '1' : '0'), (byte & 0x01 ? '1' : '0')); }


								bool spi_start_adv(void) {

								    bool status = spi_start(PMW3360_CS_PIN, PMW3360_SPI_LSBFIRST, PMW3360_SPI_MODE, PMW3360_SPI_DIVISOR);

								    wait_us(1);

								    return status;

								}


								void spi_stop_adv(void) {

								    wait_us(1);

								    spi_stop();

								}


								spi_status_t spi_write_adv(uint8_t reg_addr, uint8_t data) {

								    if (reg_addr != REG_Motion_Burst) {

								        _inBurst = false;

								    }


								    spi_start_adv();

								    // send address of the register, with MSBit = 1 to indicate it's a write

								    spi_status_t status = spi_write(reg_addr | 0x80);

								    status              = spi_write(data);


								    // tSCLK-NCS for write operation

								    wait_us(20);


								    // tSWW/tSWR (=120us) minus tSCLK-NCS. Could be shortened, but is looks like a safe lower bound

								    wait_us(100);

								    spi_stop();

								    return status;

								}


								uint8_t spi_read_adv(uint8_t reg_addr) {

								    spi_start_adv();

								    // send adress of the register, with MSBit = 0 to indicate it's a read

								    spi_write(reg_addr & 0x7f);


								    uint8_t data = spi_read();


								    // tSCLK-NCS for read operation is 120ns

								    wait_us(1);


								    //  tSRW/tSRR (=20us) minus tSCLK-NCS

								    wait_us(19);


								    spi_stop();

								    return data;

								}


								void pmw_set_cpi(uint16_t cpi) {

								    uint8_t cpival = constrain((cpi / 100) - 1, 0, 0x77);  // limits to 0--119


								    spi_start_adv();

								    spi_write_adv(REG_Config1, cpival);

								    spi_stop();

								}


								uint16_t pmw_get_cpi(void) {

								    uint8_t cpival = spi_read_adv(REG_Config1);

								    return (uint16_t)(cpival & 0xFF) * 100;

								}


								bool pmw_spi_init(void) {

								    setPinOutput(PMW3360_CS_PIN);


								    spi_init();

								    _inBurst = false;


								    spi_stop();

								    spi_start_adv();

								    spi_stop();


								    spi_write_adv(REG_Shutdown, 0xb6);  // Shutdown first

								    wait_ms(300);


								    spi_start_adv();

								    wait_us(40);

								    spi_stop_adv();

								    wait_us(40);


								    spi_write_adv(REG_Power_Up_Reset, 0x5a);

								    wait_ms(50);


								    spi_read_adv(REG_Motion);

								    spi_read_adv(REG_Delta_X_L);

								    spi_read_adv(REG_Delta_X_H);

								    spi_read_adv(REG_Delta_Y_L);

								    spi_read_adv(REG_Delta_Y_H);


								    pmw_upload_firmware();


								    spi_stop_adv();


								    wait_ms(10);

								    pmw_set_cpi(PMW3360_CPI);


								    wait_ms(1);


								    spi_write_adv(REG_Config2, 0x00);


								    spi_write_adv(REG_Angle_Tune, constrain(ROTATIONAL_TRANSFORM_ANGLE, -30, 30));


								    bool init_success = pmw_check_signature();


								    writePinLow(PMW3360_CS_PIN);


								    return init_success;

								}


								void pmw_upload_firmware(void) {

								    spi_write_adv(REG_SROM_Enable, 0x1d);


								    wait_ms(10);


								    spi_write_adv(REG_SROM_Enable, 0x18);


								    spi_start_adv();

								    spi_write(REG_SROM_Load_Burst | 0x80);

								    wait_us(15);


								    unsigned char c;

								    for (int i = 0; i < FIRMWARE_LENGTH; i++) {

								        c = (unsigned char)pgm_read_byte(firmware_data + i);

								        spi_write(c);

								        wait_us(15);

								    }

								    wait_us(200);


								    spi_read_adv(REG_SROM_ID);


								    spi_write_adv(REG_Config2, 0x00);


								    spi_stop();

								    wait_ms(10);

								}


								bool pmw_check_signature(void) {

								    uint8_t pid      = spi_read_adv(REG_Product_ID);

								    uint8_t iv_pid   = spi_read_adv(REG_Inverse_Product_ID);

								    uint8_t SROM_ver = spi_read_adv(REG_SROM_ID);

								    return (pid == 0x42 && iv_pid == 0xBD && SROM_ver == 0x04);  // signature for SROM 0x04

								}


								report_pmw_t pmw_read_burst(void) {

								    if (!_inBurst) {

								        dprintf("burst on");

								        spi_write_adv(REG_Motion_Burst, 0x00);

								        _inBurst = true;

								    }


								    spi_start_adv();

								    spi_write(REG_Motion_Burst);

								    wait_us(35);  // waits for tSRAD


								    report_pmw_t data;

								    data.motion = 0;

								    data.dx     = 0;

								    data.mdx    = 0;

								    data.dy     = 0;

								    data.mdx    = 0;


								    data.motion = spi_read();

								    spi_write(0x00);  // skip Observation

								    data.dx  = spi_read();

								    data.mdx = spi_read();

								    data.dy  = spi_read();

								    data.mdy = spi_read();


								    spi_stop();


								    if (debug_mouse) {

								        print_byte(data.motion);

								        print_byte(data.dx);

								        print_byte(data.mdx);

								        print_byte(data.dy);

								        print_byte(data.mdy);

								        dprintf("\n");

								    }


								    data.isMotion    = (data.motion & 0x80) != 0;

								    data.isOnSurface = (data.motion & 0x08) == 0;

								    data.dx |= (data.mdx << 8);

								    data.dx = data.dx * -1;

								    data.dy |= (data.mdy << 8);

								    data.dy = data.dy * -1;


								    spi_stop();


								    if (data.motion & 0b111) {  // panic recovery, sometimes burst mode works weird.

								        _inBurst = false;

								    }


								    return data;

								}