/* * Copyright (c) 2017 Nordic Semiconductor ASA * * SPDX-License-Identifier: Apache-2.0 */ #include #include "pwm.h" #define SYS_LOG_DOMAIN "pwm/nrf5_sw" #define SYS_LOG_LEVEL CONFIG_SYS_LOG_PWM_LEVEL #include struct pwm_config { NRF_TIMER_Type *timer; u8_t gpiote_base; u8_t ppi_base; u8_t map_size; }; struct chan_map { u32_t pwm; u32_t pulse_cycles; }; struct pwm_data { u32_t period_cycles; struct chan_map map[]; }; static u32_t pwm_period_check(struct pwm_data *data, u8_t map_size, u32_t pwm, u32_t period_cycles, u32_t pulse_cycles) { u8_t i; /* allow 0% and 100% duty cycle, as it does not use PWM. */ if ((pulse_cycles == 0) || (pulse_cycles == period_cycles)) { return 0; } /* fail if requested period does not match already running period */ for (i = 0; i < map_size; i++) { if ((data->map[i].pwm != pwm) && (data->map[i].pulse_cycles != 0) && (period_cycles != data->period_cycles)) { return -EINVAL; } } return 0; } static u8_t pwm_channel_map(struct pwm_data *data, u8_t map_size, u32_t pwm) { u8_t i; /* find pin, if already present */ for (i = 0; i < map_size; i++) { if (pwm == data->map[i].pwm) { return i; } } /* find a free entry */ i = map_size; while (i--) { if (data->map[i].pulse_cycles == 0) { break; } } return i; } static int pwm_nrf5_sw_pin_set(struct device *dev, u32_t pwm, u32_t period_cycles, u32_t pulse_cycles) { struct pwm_config *config; NRF_TIMER_Type *timer; struct pwm_data *data; u8_t ppi_index; u8_t channel; u16_t div; u32_t ret; config = (struct pwm_config *)dev->config->config_info; timer = config->timer; data = dev->driver_data; /* check if requested period is allowed while other channels are * active. */ ret = pwm_period_check(data, config->map_size, pwm, period_cycles, pulse_cycles); if (ret) { SYS_LOG_ERR("Incompatible period"); return ret; } /* map pwm pin to GPIOTE config/channel */ channel = pwm_channel_map(data, config->map_size, pwm); if (channel >= config->map_size) { SYS_LOG_ERR("No more channels available"); return -ENOMEM; } SYS_LOG_DBG("PWM %d, period %u, pulse %u", pwm, period_cycles, pulse_cycles); /* clear GPIOTE config */ NRF_GPIOTE->CONFIG[config->gpiote_base + channel] = 0; /* clear PPI used */ ppi_index = config->ppi_base + (channel << 1); NRF_PPI->CHENCLR = BIT(ppi_index) | BIT(ppi_index + 1); /* configure GPIO pin as output */ NRF_GPIO->DIRSET = BIT(pwm); if (pulse_cycles == 0) { /* 0% duty cycle, keep pin low */ NRF_GPIO->OUTCLR = BIT(pwm); goto pin_set_pwm_off; } else if (pulse_cycles == period_cycles) { /* 100% duty cycle, keep pin high */ NRF_GPIO->OUTSET = BIT(pwm); goto pin_set_pwm_off; } else { /* x% duty cycle, start PWM with pin low */ NRF_GPIO->OUTCLR = BIT(pwm); } /* TODO: if the assigned NRF_TIMER supports higher bit resolution, * use that info in config struct and setup accordingly. */ /* calc div, to scale down to fit in 16 bits */ div = period_cycles >> 16; /* setup HF timer in 16MHz frequency */ timer->MODE = TIMER_MODE_MODE_Timer; timer->PRESCALER = 0; timer->BITMODE = TIMER_BITMODE_BITMODE_16Bit; timer->EVENTS_COMPARE[channel] = 0; timer->EVENTS_COMPARE[config->map_size] = 0; /* TODO: set shorts according to map_size if not 3, i.e. if NRF_TIMER * supports more than 4 compares, then more channels can be supported. */ timer->SHORTS = TIMER_SHORTS_COMPARE3_CLEAR_Msk; timer->CC[channel] = pulse_cycles >> div; timer->CC[config->map_size] = period_cycles >> div; timer->TASKS_CLEAR = 1; /* configure GPIOTE, toggle with initialise output high */ NRF_GPIOTE->CONFIG[config->gpiote_base + channel] = 0x00130003 | (pwm << 8); /* setup PPI */ NRF_PPI->CH[ppi_index].EEP = (u32_t) &(timer->EVENTS_COMPARE[channel]); NRF_PPI->CH[ppi_index].TEP = (u32_t) &(NRF_GPIOTE->TASKS_OUT[channel]); NRF_PPI->CH[ppi_index + 1].EEP = (u32_t) &(timer->EVENTS_COMPARE[3]); NRF_PPI->CH[ppi_index + 1].TEP = (u32_t) &(NRF_GPIOTE->TASKS_OUT[channel]); NRF_PPI->CHENSET = BIT(ppi_index) | BIT(ppi_index + 1); /* start timer, hence PWM */ timer->TASKS_START = 1; /* store the pwm/pin and its param */ data->period_cycles = period_cycles; data->map[channel].pwm = pwm; data->map[channel].pulse_cycles = pulse_cycles; return 0; pin_set_pwm_off: data->map[channel].pulse_cycles = 0; bool pwm_active = false; /* stop timer if all channels are inactive */ for (channel = 0; channel < config->map_size; channel++) { if (data->map[channel].pulse_cycles) { pwm_active = true; break; } } if (!pwm_active) { /* No active PWM, stop timer */ timer->TASKS_STOP = 1; } return 0; } static int pwm_nrf5_sw_get_cycles_per_sec(struct device *dev, u32_t pwm, u64_t *cycles) { struct pwm_config *config; config = (struct pwm_config *)dev->config->config_info; /* HF timer frequency is derived from 16MHz source and prescaler is 0 */ *cycles = 16 * 1024 * 1024; return 0; } static const struct pwm_driver_api pwm_nrf5_sw_drv_api_funcs = { .pin_set = pwm_nrf5_sw_pin_set, .get_cycles_per_sec = pwm_nrf5_sw_get_cycles_per_sec, }; static int pwm_nrf5_sw_init(struct device *dev) { return 0; } #define PWM_0_MAP_SIZE 3 /* NOTE: nRF51x BLE controller use HW tIFS hence using only PPI channels 0-6. * nRF52x BLE controller implements SW tIFS and uses addition 6 PPI channels. * Also, nRF52x requires one additional PPI channel for decryption rate boost. * Hence, nRF52x BLE controller uses PPI channels 0-13. * * NOTE: If PA/LNA feature is enabled for nRF52x, then additional two PPI * channels 14-15 are used by BLE controller. */ static const struct pwm_config pwm_nrf5_sw_0_config = { #if defined(CONFIG_SOC_SERIES_NRF51X) .timer = NRF_TIMER1, .ppi_base = 7, #else .timer = NRF_TIMER2, .ppi_base = 14, #endif .gpiote_base = 0, .map_size = PWM_0_MAP_SIZE, }; #define PWM_0_DATA_SIZE (offsetof(struct pwm_data, map) + \ sizeof(struct chan_map) * PWM_0_MAP_SIZE) static u8_t pwm_nrf5_sw_0_data[PWM_0_DATA_SIZE]; DEVICE_AND_API_INIT(pwm_nrf5_sw_0, CONFIG_PWM_NRF5_SW_0_DEV_NAME, pwm_nrf5_sw_init, pwm_nrf5_sw_0_data, &pwm_nrf5_sw_0_config, POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE, &pwm_nrf5_sw_drv_api_funcs);