426 lines
11 KiB
C
426 lines
11 KiB
C
/*
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* Copyright (c) 2017 Nordic Semiconductor ASA
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#define DT_DRV_COMPAT nordic_nrf_sw_pwm
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#include <soc.h>
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#include <zephyr/drivers/pwm.h>
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#include <zephyr/dt-bindings/gpio/gpio.h>
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#include <nrfx_gpiote.h>
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#include <helpers/nrfx_gppi.h>
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#include <hal/nrf_gpio.h>
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#include <hal/nrf_rtc.h>
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#include <hal/nrf_timer.h>
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#include <zephyr/logging/log.h>
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LOG_MODULE_REGISTER(pwm_nrf_sw, CONFIG_PWM_LOG_LEVEL);
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#define GENERATOR_NODE DT_INST_PHANDLE(0, generator)
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#define GENERATOR_CC_NUM DT_PROP(GENERATOR_NODE, cc_num)
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#if DT_NODE_HAS_COMPAT(GENERATOR_NODE, nordic_nrf_rtc)
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#define USE_RTC 1
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#define GENERATOR_ADDR ((NRF_RTC_Type *) DT_REG_ADDR(GENERATOR_NODE))
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#define GENERATOR_BITS 24
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BUILD_ASSERT(DT_INST_PROP(0, clock_prescaler) == 0,
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"Only clock-prescaler = <0> is supported when used with RTC");
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#else
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#define USE_RTC 0
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#define GENERATOR_ADDR ((NRF_TIMER_Type *) DT_REG_ADDR(GENERATOR_NODE))
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#define GENERATOR_BITS DT_PROP(GENERATOR_NODE, max_bit_width)
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#endif
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#define PWM_0_MAP_SIZE DT_INST_PROP_LEN(0, channel_gpios)
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/* One compare channel is needed to set the PWM period, hence +1. */
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#if ((PWM_0_MAP_SIZE + 1) > GENERATOR_CC_NUM)
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#error "Invalid number of PWM channels configured."
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#endif
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#if defined(PPI_FEATURE_FORKS_PRESENT) || defined(DPPI_PRESENT)
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#define PPI_FORK_AVAILABLE 1
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#else
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#define PPI_FORK_AVAILABLE 0
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#endif
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/* When RTC is used, one more PPI task endpoint is required for clearing
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* the counter, so when FORK feature is not available, one more PPI channel
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* needs to be used.
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*/
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#if USE_RTC && !PPI_FORK_AVAILABLE
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#define PPI_PER_CH 3
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#else
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#define PPI_PER_CH 2
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#endif
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struct pwm_config {
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union {
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NRF_RTC_Type *rtc;
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NRF_TIMER_Type *timer;
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};
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uint8_t psel_ch[PWM_0_MAP_SIZE];
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uint8_t initially_inverted;
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uint8_t map_size;
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uint8_t prescaler;
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};
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struct pwm_data {
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uint32_t period_cycles;
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uint32_t pulse_cycles[PWM_0_MAP_SIZE];
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uint8_t ppi_ch[PWM_0_MAP_SIZE][PPI_PER_CH];
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uint8_t gpiote_ch[PWM_0_MAP_SIZE];
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};
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static inline NRF_RTC_Type *pwm_config_rtc(const struct pwm_config *config)
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{
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#if USE_RTC
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return config->rtc;
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#else
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return NULL;
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#endif
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}
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static inline NRF_TIMER_Type *pwm_config_timer(const struct pwm_config *config)
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{
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#if !USE_RTC
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return config->timer;
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#else
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return NULL;
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#endif
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}
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static uint32_t pwm_period_check(struct pwm_data *data, uint8_t map_size,
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uint32_t channel, uint32_t period_cycles,
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uint32_t pulse_cycles)
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{
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uint8_t i;
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/* allow 0% and 100% duty cycle, as it does not use PWM. */
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if ((pulse_cycles == 0U) || (pulse_cycles == period_cycles)) {
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return 0;
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}
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/* fail if requested period does not match already running period */
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for (i = 0U; i < map_size; i++) {
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if ((i != channel) &&
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(data->pulse_cycles[i] != 0U) &&
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(period_cycles != data->period_cycles)) {
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return -EINVAL;
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}
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}
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return 0;
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}
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static int pwm_nrf_sw_set_cycles(const struct device *dev, uint32_t channel,
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uint32_t period_cycles, uint32_t pulse_cycles,
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pwm_flags_t flags)
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{
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const struct pwm_config *config = dev->config;
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NRF_TIMER_Type *timer = pwm_config_timer(config);
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NRF_RTC_Type *rtc = pwm_config_rtc(config);
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struct pwm_data *data = dev->data;
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uint32_t ppi_mask;
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uint8_t active_level;
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uint8_t psel_ch;
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uint8_t gpiote_ch;
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const uint8_t *ppi_chs;
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int ret;
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if (channel >= config->map_size) {
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LOG_ERR("Invalid channel: %u.", channel);
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return -EINVAL;
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}
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/* check if requested period is allowed while other channels are
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* active.
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*/
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ret = pwm_period_check(data, config->map_size, channel, period_cycles,
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pulse_cycles);
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if (ret) {
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LOG_ERR("Incompatible period");
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return ret;
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}
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if (USE_RTC) {
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/* pulse_cycles - 1 is written to 24-bit CC */
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if (period_cycles > BIT_MASK(24) + 1) {
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LOG_ERR("Too long period (%u)!", period_cycles);
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return -EINVAL;
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}
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} else {
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if (GENERATOR_BITS < 32 &&
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period_cycles > BIT_MASK(GENERATOR_BITS)) {
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LOG_ERR("Too long period (%u), adjust PWM prescaler!",
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period_cycles);
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return -EINVAL;
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}
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}
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psel_ch = config->psel_ch[channel];
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gpiote_ch = data->gpiote_ch[channel];
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ppi_chs = data->ppi_ch[channel];
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LOG_DBG("channel %u, period %u, pulse %u",
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channel, period_cycles, pulse_cycles);
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/* clear PPI used */
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ppi_mask = BIT(ppi_chs[0]) | BIT(ppi_chs[1]) |
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(PPI_PER_CH > 2 ? BIT(ppi_chs[2]) : 0);
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nrfx_gppi_channels_disable(ppi_mask);
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active_level = (flags & PWM_POLARITY_INVERTED) ? 0 : 1;
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/*
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* If the duty cycle is 0% or 100%, there is no need to generate
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* the PWM signal, just keep the output pin in inactive or active
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* state, respectively.
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*/
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if (pulse_cycles == 0 || pulse_cycles == period_cycles) {
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nrf_gpio_pin_write(psel_ch,
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pulse_cycles == 0 ? !active_level
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: active_level);
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/* clear GPIOTE config */
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nrf_gpiote_te_default(NRF_GPIOTE, gpiote_ch);
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/* No PWM generation for this channel. */
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data->pulse_cycles[channel] = 0U;
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/* Check if PWM signal is generated on any channel. */
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for (uint8_t i = 0; i < config->map_size; i++) {
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if (data->pulse_cycles[i]) {
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return 0;
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}
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}
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/* No PWM generation needed, stop the timer. */
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if (USE_RTC) {
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nrf_rtc_task_trigger(rtc, NRF_RTC_TASK_STOP);
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} else {
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nrf_timer_task_trigger(timer, NRF_TIMER_TASK_STOP);
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}
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return 0;
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}
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/* configure RTC / TIMER */
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if (USE_RTC) {
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nrf_rtc_event_clear(rtc,
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nrf_rtc_compare_event_get(1 + channel));
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nrf_rtc_event_clear(rtc,
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nrf_rtc_compare_event_get(0));
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/*
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* '- 1' adjusts pulse and period cycles to the fact that CLEAR
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* task event is generated always one LFCLK cycle after period
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* COMPARE value is reached.
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*/
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nrf_rtc_cc_set(rtc, 1 + channel, pulse_cycles - 1);
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nrf_rtc_cc_set(rtc, 0, period_cycles - 1);
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nrf_rtc_task_trigger(rtc, NRF_RTC_TASK_CLEAR);
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} else {
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nrf_timer_event_clear(timer,
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nrf_timer_compare_event_get(1 + channel));
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nrf_timer_event_clear(timer,
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nrf_timer_compare_event_get(0));
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nrf_timer_cc_set(timer, 1 + channel, pulse_cycles);
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nrf_timer_cc_set(timer, 0, period_cycles);
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nrf_timer_task_trigger(timer, NRF_TIMER_TASK_CLEAR);
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}
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/* Configure GPIOTE - toggle task with proper initial output value. */
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NRF_GPIOTE->CONFIG[gpiote_ch] =
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(GPIOTE_CONFIG_MODE_Task << GPIOTE_CONFIG_MODE_Pos) |
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((uint32_t)psel_ch << 8) |
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(GPIOTE_CONFIG_POLARITY_Toggle << GPIOTE_CONFIG_POLARITY_Pos) |
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((uint32_t)active_level << GPIOTE_CONFIG_OUTINIT_Pos);
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/* setup PPI */
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uint32_t pulse_end_event_address, period_end_event_address;
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nrf_gpiote_task_t pulse_end_task, period_end_task;
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#if defined(GPIOTE_FEATURE_SET_PRESENT) && defined(GPIOTE_FEATURE_CLR_PRESENT)
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if (active_level == 0) {
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pulse_end_task = nrf_gpiote_set_task_get(gpiote_ch);
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period_end_task = nrf_gpiote_clr_task_get(gpiote_ch);
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} else {
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pulse_end_task = nrf_gpiote_clr_task_get(gpiote_ch);
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period_end_task = nrf_gpiote_set_task_get(gpiote_ch);
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}
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#else
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pulse_end_task = period_end_task = nrf_gpiote_out_task_get(gpiote_ch);
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#endif
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uint32_t pulse_end_task_address =
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nrf_gpiote_task_address_get(NRF_GPIOTE, pulse_end_task);
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uint32_t period_end_task_address =
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nrf_gpiote_task_address_get(NRF_GPIOTE, period_end_task);
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if (USE_RTC) {
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uint32_t clear_task_address =
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nrf_rtc_event_address_get(rtc, NRF_RTC_TASK_CLEAR);
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pulse_end_event_address =
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nrf_rtc_event_address_get(rtc,
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nrf_rtc_compare_event_get(1 + channel));
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period_end_event_address =
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nrf_rtc_event_address_get(rtc,
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nrf_rtc_compare_event_get(0));
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#if PPI_FORK_AVAILABLE
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nrfx_gppi_fork_endpoint_setup(ppi_chs[1],
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clear_task_address);
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#else
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nrfx_gppi_channel_endpoints_setup(ppi_chs[2],
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period_end_event_address,
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clear_task_address);
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#endif
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} else {
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pulse_end_event_address =
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nrf_timer_event_address_get(timer,
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nrf_timer_compare_event_get(1 + channel));
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period_end_event_address =
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nrf_timer_event_address_get(timer,
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nrf_timer_compare_event_get(0));
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}
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nrfx_gppi_channel_endpoints_setup(ppi_chs[0],
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pulse_end_event_address,
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pulse_end_task_address);
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nrfx_gppi_channel_endpoints_setup(ppi_chs[1],
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period_end_event_address,
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period_end_task_address);
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nrfx_gppi_channels_enable(ppi_mask);
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/* start timer, hence PWM */
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if (USE_RTC) {
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nrf_rtc_task_trigger(rtc, NRF_RTC_TASK_START);
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} else {
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nrf_timer_task_trigger(timer, NRF_TIMER_TASK_START);
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}
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/* store the period and pulse cycles */
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data->period_cycles = period_cycles;
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data->pulse_cycles[channel] = pulse_cycles;
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return 0;
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}
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static int pwm_nrf_sw_get_cycles_per_sec(const struct device *dev,
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uint32_t channel, uint64_t *cycles)
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{
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const struct pwm_config *config = dev->config;
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if (USE_RTC) {
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/*
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* RTC frequency is derived from 32768Hz source without any
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* prescaler
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*/
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*cycles = 32768UL;
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} else {
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/*
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* HF timer frequency is derived from 16MHz source with a
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* prescaler
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*/
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*cycles = 16000000UL / BIT(config->prescaler);
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}
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return 0;
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}
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static const struct pwm_driver_api pwm_nrf_sw_drv_api_funcs = {
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.set_cycles = pwm_nrf_sw_set_cycles,
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.get_cycles_per_sec = pwm_nrf_sw_get_cycles_per_sec,
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};
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static int pwm_nrf_sw_init(const struct device *dev)
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{
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const struct pwm_config *config = dev->config;
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struct pwm_data *data = dev->data;
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NRF_TIMER_Type *timer = pwm_config_timer(config);
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NRF_RTC_Type *rtc = pwm_config_rtc(config);
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for (uint32_t i = 0; i < config->map_size; i++) {
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nrfx_err_t err;
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/* Allocate resources. */
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for (uint32_t j = 0; j < PPI_PER_CH; j++) {
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err = nrfx_gppi_channel_alloc(&data->ppi_ch[i][j]);
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if (err != NRFX_SUCCESS) {
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/* Do not free allocated resource. It is a fatal condition,
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* system requires reconfiguration.
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*/
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LOG_ERR("Failed to allocate PPI channel");
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return -ENOMEM;
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}
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}
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err = nrfx_gpiote_channel_alloc(&data->gpiote_ch[i]);
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if (err != NRFX_SUCCESS) {
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/* Do not free allocated resource. It is a fatal condition,
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* system requires reconfiguration.
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*/
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LOG_ERR("Failed to allocate GPIOTE channel");
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return -ENOMEM;
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}
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/* Set initial state of the output pins. */
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nrf_gpio_pin_write(config->psel_ch[i],
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(config->initially_inverted & BIT(i)) ? 1 : 0);
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nrf_gpio_cfg_output(config->psel_ch[i]);
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}
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if (USE_RTC) {
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/* setup RTC */
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nrf_rtc_prescaler_set(rtc, 0);
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nrf_rtc_event_enable(rtc, NRF_RTC_INT_COMPARE0_MASK |
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NRF_RTC_INT_COMPARE1_MASK |
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NRF_RTC_INT_COMPARE2_MASK |
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NRF_RTC_INT_COMPARE3_MASK);
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} else {
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/* setup HF timer */
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nrf_timer_mode_set(timer, NRF_TIMER_MODE_TIMER);
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nrf_timer_prescaler_set(timer, config->prescaler);
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nrf_timer_bit_width_set(timer,
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GENERATOR_BITS == 32 ? NRF_TIMER_BIT_WIDTH_32
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: NRF_TIMER_BIT_WIDTH_16);
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nrf_timer_shorts_enable(timer,
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NRF_TIMER_SHORT_COMPARE0_CLEAR_MASK);
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}
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return 0;
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}
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#define PSEL_AND_COMMA(_node_id, _prop, _idx) \
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NRF_DT_GPIOS_TO_PSEL_BY_IDX(_node_id, _prop, _idx),
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#define ACTIVE_LOW_BITS(_node_id, _prop, _idx) \
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((DT_GPIO_FLAGS_BY_IDX(_node_id, _prop, _idx) & GPIO_ACTIVE_LOW) \
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? BIT(_idx) : 0) |
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static const struct pwm_config pwm_nrf_sw_0_config = {
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COND_CODE_1(USE_RTC, (.rtc), (.timer)) = GENERATOR_ADDR,
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.psel_ch = {
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DT_INST_FOREACH_PROP_ELEM(0, channel_gpios, PSEL_AND_COMMA)
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},
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.initially_inverted =
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DT_INST_FOREACH_PROP_ELEM(0, channel_gpios, ACTIVE_LOW_BITS) 0,
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.map_size = PWM_0_MAP_SIZE,
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.prescaler = DT_INST_PROP(0, clock_prescaler),
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};
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static struct pwm_data pwm_nrf_sw_0_data;
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DEVICE_DT_INST_DEFINE(0,
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pwm_nrf_sw_init,
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NULL,
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&pwm_nrf_sw_0_data,
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&pwm_nrf_sw_0_config,
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POST_KERNEL,
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CONFIG_PWM_INIT_PRIORITY,
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&pwm_nrf_sw_drv_api_funcs);
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