318 lines
12 KiB
C
318 lines
12 KiB
C
/* Copyright 2023 Cipulot
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "ec_switch_matrix.h"
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#include "analog.h"
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#include "atomic_util.h"
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#include "math.h"
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#include "print.h"
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#include "wait.h"
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#if defined(__AVR__)
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# error "AVR platforms not supported due to a variety of reasons. Among them there are limited memory, limited number of pins and ADC not being able to give satisfactory results."
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#endif
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#define OPEN_DRAIN_SUPPORT defined(PAL_MODE_OUTPUT_OPENDRAIN)
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eeprom_ec_config_t eeprom_ec_config;
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ec_config_t ec_config;
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// Pin and port array
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const pin_t row_pins[] = MATRIX_ROW_PINS;
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const pin_t amux_sel_pins[] = AMUX_SEL_PINS;
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const pin_t amux_en_pins[] = AMUX_EN_PINS;
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const pin_t amux_n_col_sizes[] = AMUX_COL_CHANNELS_SIZES;
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const pin_t amux_n_col_channels[][AMUX_MAX_COLS_COUNT] = {AMUX_COL_CHANNELS};
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#define AMUX_SEL_PINS_COUNT ARRAY_SIZE(amux_sel_pins)
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#define EXPECTED_AMUX_SEL_PINS_COUNT ceil(log2(AMUX_MAX_COLS_COUNT)
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// Checks for the correctness of the configuration
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_Static_assert(ARRAY_SIZE(amux_en_pins) == AMUX_COUNT, "AMUX_EN_PINS doesn't have the minimum number of bits required to enable all the multiplexers available");
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// Check that number of select pins is enough to select all the channels
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_Static_assert(AMUX_SEL_PINS_COUNT == EXPECTED_AMUX_SEL_PINS_COUNT), "AMUX_SEL_PINS doesn't have the minimum number of bits required address all the channels");
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// Check that number of elements in AMUX_COL_CHANNELS_SIZES is enough to specify the number of channels for all the multiplexers available
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_Static_assert(ARRAY_SIZE(amux_n_col_sizes) == AMUX_COUNT, "AMUX_COL_CHANNELS_SIZES doesn't have the minimum number of elements required to specify the number of channels for all the multiplexers available");
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static uint16_t sw_value[MATRIX_ROWS][MATRIX_COLS];
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static adc_mux adcMux;
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// Initialize the row pins
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void init_row(void) {
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// Set all row pins as output and low
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for (uint8_t idx = 0; idx < MATRIX_ROWS; idx++) {
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gpio_set_pin_output(row_pins[idx]);
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gpio_write_pin_low(row_pins[idx]);
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}
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}
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// Initialize the multiplexers
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void init_amux(void) {
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for (uint8_t idx = 0; idx < AMUX_COUNT; idx++) {
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gpio_set_pin_output(amux_en_pins[idx]);
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gpio_write_pin_low(amux_en_pins[idx]);
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}
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for (uint8_t idx = 0; idx < AMUX_SEL_PINS_COUNT; idx++) {
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gpio_set_pin_output(amux_sel_pins[idx]);
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}
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}
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// Select the multiplexer channel of the specified multiplexer
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void select_amux_channel(uint8_t channel, uint8_t col) {
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// Get the channel for the specified multiplexer
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uint8_t ch = amux_n_col_channels[channel][col];
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// momentarily disable specified multiplexer
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gpio_write_pin_high(amux_en_pins[channel]);
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// Select the multiplexer channel
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for (uint8_t i = 0; i < AMUX_SEL_PINS_COUNT; i++) {
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gpio_write_pin(amux_sel_pins[i], ch & (1 << i));
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}
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// re enable specified multiplexer
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gpio_write_pin_low(amux_en_pins[channel]);
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}
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// Disable all the unused multiplexers
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void disable_unused_amux(uint8_t channel) {
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// disable all the other multiplexers apart from the current selected one
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for (uint8_t idx = 0; idx < AMUX_COUNT; idx++) {
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if (idx != channel) {
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gpio_write_pin_high(amux_en_pins[idx]);
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}
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}
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}
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// Discharge the peak hold capacitor
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void discharge_capacitor(void) {
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#ifdef OPEN_DRAIN_SUPPORT
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gpio_write_pin_low(DISCHARGE_PIN);
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#else
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gpio_write_pin_low(DISCHARGE_PIN);
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gpio_set_pin_output(DISCHARGE_PIN);
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#endif
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}
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// Charge the peak hold capacitor
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void charge_capacitor(uint8_t row) {
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#ifdef OPEN_DRAIN_SUPPORT
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gpio_write_pin_high(DISCHARGE_PIN);
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#else
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gpio_set_pin_input(DISCHARGE_PIN);
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#endif
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gpio_write_pin_high(row_pins[row]);
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}
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// Initialize the peripherals pins
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int ec_init(void) {
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// Initialize ADC
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palSetLineMode(ANALOG_PORT, PAL_MODE_INPUT_ANALOG);
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adcMux = pinToMux(ANALOG_PORT);
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// Dummy call to make sure that adcStart() has been called in the appropriate state
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adc_read(adcMux);
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// Initialize discharge pin as discharge mode
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gpio_write_pin_low(DISCHARGE_PIN);
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#ifdef OPEN_DRAIN_SUPPORT
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gpio_set_pin_output_open_drain(DISCHARGE_PIN);
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#else
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gpio_set_pin_output(DISCHARGE_PIN);
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#endif
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// Initialize drive lines
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init_row();
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// Initialize AMUXs
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init_amux();
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return 0;
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}
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// Get the noise floor
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void ec_noise_floor(void) {
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// Initialize the noise floor
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for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
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for (uint8_t col = 0; col < MATRIX_COLS; col++) {
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ec_config.noise_floor[row][col] = 0;
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}
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}
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// Sample the noise floor
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for (uint8_t i = 0; i < DEFAULT_NOISE_FLOOR_SAMPLING_COUNT; i++) {
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for (uint8_t amux = 0; amux < AMUX_COUNT; amux++) {
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disable_unused_amux(amux);
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for (uint8_t col = 0; col < amux_n_col_sizes[amux]; col++) {
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uint8_t sum = 0;
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for (uint8_t i = 0; i < (amux > 0 ? amux : 0); i++)
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sum += amux_n_col_sizes[i];
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uint8_t adjusted_col = col + sum;
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for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
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ec_config.noise_floor[row][adjusted_col] += ec_readkey_raw(amux, row, col);
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}
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}
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}
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wait_ms(5);
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}
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// Average the noise floor
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for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
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for (uint8_t col = 0; col < MATRIX_COLS; col++) {
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ec_config.noise_floor[row][col] /= DEFAULT_NOISE_FLOOR_SAMPLING_COUNT;
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}
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}
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}
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// Scan key values and update matrix state
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bool ec_matrix_scan(matrix_row_t current_matrix[]) {
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bool updated = false;
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for (uint8_t amux = 0; amux < AMUX_COUNT; amux++) {
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disable_unused_amux(amux);
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for (uint8_t col = 0; col < amux_n_col_sizes[amux]; col++) {
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for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
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uint8_t sum = 0;
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for (uint8_t i = 0; i < (amux > 0 ? amux : 0); i++)
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sum += amux_n_col_sizes[i];
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uint8_t adjusted_col = col + sum;
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sw_value[row][adjusted_col] = ec_readkey_raw(amux, row, col);
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if (ec_config.bottoming_calibration) {
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if (ec_config.bottoming_calibration_starter[row][adjusted_col]) {
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ec_config.bottoming_reading[row][adjusted_col] = sw_value[row][adjusted_col];
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ec_config.bottoming_calibration_starter[row][adjusted_col] = false;
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} else if (sw_value[row][adjusted_col] > ec_config.bottoming_reading[row][adjusted_col]) {
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ec_config.bottoming_reading[row][adjusted_col] = sw_value[row][adjusted_col];
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}
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} else {
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updated |= ec_update_key(¤t_matrix[row], row, adjusted_col, sw_value[row][adjusted_col]);
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}
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}
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}
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}
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return ec_config.bottoming_calibration ? false : updated;
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}
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// Read the capacitive sensor value
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uint16_t ec_readkey_raw(uint8_t channel, uint8_t row, uint8_t col) {
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uint16_t sw_value = 0;
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// Select the multiplexer
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select_amux_channel(channel, col);
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// Set the row pin to low state to avoid ghosting
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gpio_write_pin_low(row_pins[row]);
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ATOMIC_BLOCK_FORCEON {
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// Set the row pin to high state and have capacitor charge
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charge_capacitor(row);
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// Read the ADC value
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sw_value = adc_read(adcMux);
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}
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// Discharge peak hold capacitor
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discharge_capacitor();
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// Waiting for the ghost capacitor to discharge fully
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wait_us(DISCHARGE_TIME);
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return sw_value;
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}
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// Update press/release state of key
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bool ec_update_key(matrix_row_t* current_row, uint8_t row, uint8_t col, uint16_t sw_value) {
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bool current_state = (*current_row >> col) & 1;
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// Real Time Noise Floor Calibration
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if (sw_value < (ec_config.noise_floor[row][col] - NOISE_FLOOR_THRESHOLD)) {
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uprintf("Noise Floor Change: %d, %d, %d\n", row, col, sw_value);
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ec_config.noise_floor[row][col] = sw_value;
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ec_config.rescaled_mode_0_actuation_threshold[row][col] = rescale(ec_config.mode_0_actuation_threshold, 0, 1023, ec_config.noise_floor[row][col], eeprom_ec_config.bottoming_reading[row][col]);
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ec_config.rescaled_mode_0_release_threshold[row][col] = rescale(ec_config.mode_0_release_threshold, 0, 1023, ec_config.noise_floor[row][col], eeprom_ec_config.bottoming_reading[row][col]);
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ec_config.rescaled_mode_1_initial_deadzone_offset[row][col] = rescale(ec_config.mode_1_initial_deadzone_offset, 0, 1023, ec_config.noise_floor[row][col], eeprom_ec_config.bottoming_reading[row][col]);
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}
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// Normal board-wide APC
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if (ec_config.actuation_mode == 0) {
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if (current_state && sw_value < ec_config.rescaled_mode_0_release_threshold[row][col]) {
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*current_row &= ~(1 << col);
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uprintf("Key released: %d, %d, %d\n", row, col, sw_value);
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return true;
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}
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if ((!current_state) && sw_value > ec_config.rescaled_mode_0_actuation_threshold[row][col]) {
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*current_row |= (1 << col);
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uprintf("Key pressed: %d, %d, %d\n", row, col, sw_value);
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return true;
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}
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}
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// Rapid Trigger
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else if (ec_config.actuation_mode == 1) {
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// Is key in active zone?
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if (sw_value > ec_config.rescaled_mode_1_initial_deadzone_offset[row][col]) {
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// Is key pressed while in active zone?
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if (current_state) {
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// Is the key still moving down?
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if (sw_value > ec_config.extremum[row][col]) {
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ec_config.extremum[row][col] = sw_value;
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uprintf("Key pressed: %d, %d, %d\n", row, col, sw_value);
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}
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// Has key moved up enough to be released?
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else if (sw_value < ec_config.extremum[row][col] - ec_config.mode_1_release_offset) {
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ec_config.extremum[row][col] = sw_value;
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*current_row &= ~(1 << col);
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uprintf("Key released: %d, %d, %d\n", row, col, sw_value);
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return true;
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}
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}
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// Key is not pressed while in active zone
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else {
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// Is the key still moving up?
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if (sw_value < ec_config.extremum[row][col]) {
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ec_config.extremum[row][col] = sw_value;
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}
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// Has key moved down enough to be pressed?
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else if (sw_value > ec_config.extremum[row][col] + ec_config.mode_1_actuation_offset) {
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ec_config.extremum[row][col] = sw_value;
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*current_row |= (1 << col);
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uprintf("Key pressed: %d, %d, %d\n", row, col, sw_value);
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return true;
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}
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}
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}
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// Key is not in active zone
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else {
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// Check to avoid key being stuck in pressed state near the active zone threshold
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if (sw_value < ec_config.extremum[row][col]) {
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ec_config.extremum[row][col] = sw_value;
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*current_row &= ~(1 << col);
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return true;
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}
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}
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}
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return false;
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}
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// Print the matrix values
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void ec_print_matrix(void) {
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for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
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for (uint8_t col = 0; col < MATRIX_COLS - 1; col++) {
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uprintf("%4d,", sw_value[row][col]);
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}
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uprintf("%4d\n", sw_value[row][MATRIX_COLS - 1]);
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}
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print("\n");
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}
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// Rescale the value to a different range
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uint16_t rescale(uint16_t x, uint16_t in_min, uint16_t in_max, uint16_t out_min, uint16_t out_max) {
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return (x - in_min) * (out_max - out_min) / (in_max - in_min) + out_min;
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}
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