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


								#include "joystick.h"

								#include "process_joystick.h"


								#include "analog.h"


								#include <string.h>

								#include <math.h>


								bool process_joystick_buttons(uint16_t keycode, keyrecord_t *record);


								bool process_joystick(uint16_t keycode, keyrecord_t *record) {

								    if (process_joystick_buttons(keycode, record) && (joystick_status.status & JS_UPDATED) > 0) {

								        send_joystick_packet(&joystick_status);

								        joystick_status.status &= ~JS_UPDATED;

								    }


								    return true;

								}


								__attribute__((weak)) void joystick_task(void) {

								    if (process_joystick_analogread() && (joystick_status.status & JS_UPDATED)) {

								        send_joystick_packet(&joystick_status);

								        joystick_status.status &= ~JS_UPDATED;

								    }

								}


								bool process_joystick_buttons(uint16_t keycode, keyrecord_t *record) {

								    if (keycode < JS_BUTTON0 || keycode > JS_BUTTON_MAX) {

								        return true;

								    } else {

								        if (record->event.pressed) {

								            joystick_status.buttons[(keycode - JS_BUTTON0) / 8] |= 1 << (keycode % 8);

								        } else {

								            joystick_status.buttons[(keycode - JS_BUTTON0) / 8] &= ~(1 << (keycode % 8));

								        }


								        joystick_status.status |= JS_UPDATED;

								    }


								    return true;

								}


								uint16_t savePinState(pin_t pin) {

								#ifdef __AVR__

								    uint8_t pinNumber = pin & 0xF;

								    return ((PORTx_ADDRESS(pin) >> pinNumber) & 0x1) << 1 | ((DDRx_ADDRESS(pin) >> pinNumber) & 0x1);

								#elif defined(PROTOCOL_CHIBIOS)

								    /*

								    The pin configuration is backed up in the following format :

								 bit  15    9  8   7   6  5  4   3     2    1 0

								      |unused|ODR|IDR|PUPDR|OSPEEDR|OTYPER|MODER|

								    */

								    return ((PAL_PORT(pin)->MODER >> (2 * PAL_PAD(pin))) & 0x3) | (((PAL_PORT(pin)->OTYPER >> (1 * PAL_PAD(pin))) & 0x1) << 2) | (((PAL_PORT(pin)->OSPEEDR >> (2 * PAL_PAD(pin))) & 0x3) << 3) | (((PAL_PORT(pin)->PUPDR >> (2 * PAL_PAD(pin))) & 0x3) << 5) | (((PAL_PORT(pin)->IDR >> (1 * PAL_PAD(pin))) & 0x1) << 7) | (((PAL_PORT(pin)->ODR >> (1 * PAL_PAD(pin))) & 0x1) << 8);

								#else

								    return 0;

								#endif

								}


								void restorePinState(pin_t pin, uint16_t restoreState) {

								#if defined(PROTOCOL_LUFA)

								    uint8_t pinNumber  = pin & 0xF;

								    PORTx_ADDRESS(pin) = (PORTx_ADDRESS(pin) & ~_BV(pinNumber)) | (((restoreState >> 1) & 0x1) << pinNumber);

								    DDRx_ADDRESS(pin)  = (DDRx_ADDRESS(pin) & ~_BV(pinNumber)) | ((restoreState & 0x1) << pinNumber);

								#elif defined(PROTOCOL_CHIBIOS)

								    PAL_PORT(pin)->MODER   = (PAL_PORT(pin)->MODER & ~(0x3 << (2 * PAL_PAD(pin)))) | (restoreState & 0x3) << (2 * PAL_PAD(pin));

								    PAL_PORT(pin)->OTYPER  = (PAL_PORT(pin)->OTYPER & ~(0x1 << (1 * PAL_PAD(pin)))) | ((restoreState >> 2) & 0x1) << (1 * PAL_PAD(pin));

								    PAL_PORT(pin)->OSPEEDR = (PAL_PORT(pin)->OSPEEDR & ~(0x3 << (2 * PAL_PAD(pin)))) | ((restoreState >> 3) & 0x3) << (2 * PAL_PAD(pin));

								    PAL_PORT(pin)->PUPDR   = (PAL_PORT(pin)->PUPDR & ~(0x3 << (2 * PAL_PAD(pin)))) | ((restoreState >> 5) & 0x3) << (2 * PAL_PAD(pin));

								    PAL_PORT(pin)->IDR     = (PAL_PORT(pin)->IDR & ~(0x1 << (1 * PAL_PAD(pin)))) | ((restoreState >> 7) & 0x1) << (1 * PAL_PAD(pin));

								    PAL_PORT(pin)->ODR     = (PAL_PORT(pin)->ODR & ~(0x1 << (1 * PAL_PAD(pin)))) | ((restoreState >> 8) & 0x1) << (1 * PAL_PAD(pin));

								#else

								    return;

								#endif

								}


								__attribute__((weak)) bool process_joystick_analogread() { return process_joystick_analogread_quantum(); }


								bool process_joystick_analogread_quantum() {

								#if JOYSTICK_AXES_COUNT > 0

								    for (int axis_index = 0; axis_index < JOYSTICK_AXES_COUNT; ++axis_index) {

								        if (joystick_axes[axis_index].input_pin == JS_VIRTUAL_AXIS) {

								            continue;

								        }


								        // save previous input pin status as well

								        uint16_t inputSavedState = savePinState(joystick_axes[axis_index].input_pin);


								        // disable pull-up resistor

								        writePinLow(joystick_axes[axis_index].input_pin);


								        // if pin was a pull-up input, we need to uncharge it by turning it low

								        // before making it a low input

								        setPinOutput(joystick_axes[axis_index].input_pin);


								        wait_us(10);


								        // save and apply output pin status

								        uint16_t outputSavedState = 0;

								        if (joystick_axes[axis_index].output_pin != JS_VIRTUAL_AXIS) {

								            // save previous output pin status

								            outputSavedState = savePinState(joystick_axes[axis_index].output_pin);


								            setPinOutput(joystick_axes[axis_index].output_pin);

								            writePinHigh(joystick_axes[axis_index].output_pin);

								        }


								        uint16_t groundSavedState = 0;

								        if (joystick_axes[axis_index].ground_pin != JS_VIRTUAL_AXIS) {

								            // save previous output pin status

								            groundSavedState = savePinState(joystick_axes[axis_index].ground_pin);


								            setPinOutput(joystick_axes[axis_index].ground_pin);

								            writePinLow(joystick_axes[axis_index].ground_pin);

								        }


								        wait_us(10);


								        setPinInput(joystick_axes[axis_index].input_pin);


								        wait_us(10);


								#    if defined(__AVR__) || defined(PROTOCOL_CHIBIOS)

								        int16_t axis_val = analogReadPin(joystick_axes[axis_index].input_pin);

								#    else

								        // default to resting position

								        int16_t axis_val = joystick_axes[axis_index].mid_digit;

								#    endif


								        // test the converted value against the lower range

								        int32_t ref        = joystick_axes[axis_index].mid_digit;

								        int32_t range      = joystick_axes[axis_index].min_digit;

								        int32_t ranged_val = ((axis_val - ref) * -JOYSTICK_RESOLUTION) / (range - ref);


								        if (ranged_val > 0) {

								            // the value is in the higher range

								            range      = joystick_axes[axis_index].max_digit;

								            ranged_val = ((axis_val - ref) * JOYSTICK_RESOLUTION) / (range - ref);

								        }


								        // clamp the result in the valid range

								        ranged_val = ranged_val < -JOYSTICK_RESOLUTION ? -JOYSTICK_RESOLUTION : ranged_val;

								        ranged_val = ranged_val > JOYSTICK_RESOLUTION ? JOYSTICK_RESOLUTION : ranged_val;


								        if (ranged_val != joystick_status.axes[axis_index]) {

								            joystick_status.axes[axis_index] = ranged_val;

								            joystick_status.status |= JS_UPDATED;

								        }


								        // restore output, ground and input status

								        if (joystick_axes[axis_index].output_pin != JS_VIRTUAL_AXIS) {

								            restorePinState(joystick_axes[axis_index].output_pin, outputSavedState);

								        }

								        if (joystick_axes[axis_index].ground_pin != JS_VIRTUAL_AXIS) {

								            restorePinState(joystick_axes[axis_index].ground_pin, groundSavedState);

								        }


								        restorePinState(joystick_axes[axis_index].input_pin, inputSavedState);

								    }


								#endif

								    return true;

								}