/* * Copyright (c) 2017, NXP * Copyright (c) 2020-2021 Vestas Wind Systems A/S * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nxp_kinetis_ftm_pwm #include #include #include #include #include #include #define LOG_LEVEL CONFIG_PWM_LOG_LEVEL #include LOG_MODULE_REGISTER(pwm_mcux_ftm); #define MAX_CHANNELS ARRAY_SIZE(FTM0->CONTROLS) /* PWM capture operates on channel pairs */ #define MAX_CAPTURE_PAIRS (MAX_CHANNELS / 2U) #define PAIR_1ST_CH(pair) (pair * 2U) #define PAIR_2ND_CH(pair) (PAIR_1ST_CH(pair) + 1) struct mcux_ftm_config { FTM_Type *base; const struct device *clock_dev; clock_control_subsys_t clock_subsys; ftm_clock_source_t ftm_clock_source; ftm_clock_prescale_t prescale; uint8_t channel_count; ftm_pwm_mode_t mode; #ifdef CONFIG_PWM_CAPTURE void (*irq_config_func)(const struct device *dev); #endif /* CONFIG_PWM_CAPTURE */ }; struct mcux_ftm_capture_data { ftm_dual_edge_capture_param_t param; pwm_capture_callback_handler_t callback; void *user_data; uint32_t first_edge_overflows; bool pulse_capture; }; struct mcux_ftm_data { uint32_t clock_freq; uint32_t period_cycles; ftm_chnl_pwm_config_param_t channel[MAX_CHANNELS]; #ifdef CONFIG_PWM_CAPTURE uint32_t overflows; struct mcux_ftm_capture_data capture[MAX_CAPTURE_PAIRS]; #endif /* CONFIG_PWM_CAPTURE */ }; static int mcux_ftm_pin_set(const struct device *dev, uint32_t pwm, uint32_t period_cycles, uint32_t pulse_cycles, pwm_flags_t flags) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; status_t status; #ifdef CONFIG_PWM_CAPTURE uint32_t pair = pwm / 2U; uint32_t irqs; #endif /* CONFIG_PWM_CAPTURE */ if ((period_cycles == 0U) || (pulse_cycles > period_cycles)) { LOG_ERR("Invalid combination: period_cycles=%d, " "pulse_cycles=%d", period_cycles, pulse_cycles); return -EINVAL; } if (pwm >= config->channel_count) { LOG_ERR("Invalid channel"); return -ENOTSUP; } #ifdef CONFIG_PWM_CAPTURE irqs = FTM_GetEnabledInterrupts(config->base); if (irqs & BIT(PAIR_2ND_CH(pair))) { LOG_ERR("Cannot set PWM, capture in progress on pair %d", pair); return -EBUSY; } #endif /* CONFIG_PWM_CAPTURE */ data->channel[pwm].dutyValue = pulse_cycles; if ((flags & PWM_POLARITY_INVERTED) == 0) { data->channel[pwm].level = kFTM_HighTrue; } else { data->channel[pwm].level = kFTM_LowTrue; } LOG_DBG("pulse_cycles=%d, period_cycles=%d, flags=%d", pulse_cycles, period_cycles, flags); if (period_cycles != data->period_cycles) { #ifdef CONFIG_PWM_CAPTURE if (irqs & BIT_MASK(ARRAY_SIZE(data->channel))) { LOG_ERR("Cannot change period, capture in progress"); return -EBUSY; } #endif /* CONFIG_PWM_CAPTURE */ if (data->period_cycles != 0) { /* Only warn when not changing from zero */ LOG_WRN("Changing period cycles from %d to %d" " affects all %d channels in %s", data->period_cycles, period_cycles, config->channel_count, dev->name); } data->period_cycles = period_cycles; FTM_StopTimer(config->base); FTM_SetTimerPeriod(config->base, period_cycles); FTM_SetSoftwareTrigger(config->base, true); FTM_StartTimer(config->base, config->ftm_clock_source); } status = FTM_SetupPwmMode(config->base, data->channel, config->channel_count, config->mode); if (status != kStatus_Success) { LOG_ERR("Could not set up pwm"); return -ENOTSUP; } FTM_SetSoftwareTrigger(config->base, true); return 0; } #ifdef CONFIG_PWM_CAPTURE static int mcux_ftm_pin_configure_capture(const struct device *dev, uint32_t pwm, pwm_flags_t flags, pwm_capture_callback_handler_t cb, void *user_data) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; ftm_dual_edge_capture_param_t *param; uint32_t pair = pwm / 2U; if (pwm & 0x1U) { LOG_ERR("PWM capture only supported on even channels"); return -ENOTSUP; } if (pair >= ARRAY_SIZE(data->capture)) { LOG_ERR("Invalid channel pair %d", pair); return -EINVAL; } if (FTM_GetEnabledInterrupts(config->base) & BIT(PAIR_2ND_CH(pair))) { LOG_ERR("Capture already active on channel pair %d", pair); return -EBUSY; } if (!(flags & PWM_CAPTURE_TYPE_MASK)) { LOG_ERR("No capture type specified"); return -EINVAL; } if ((flags & PWM_CAPTURE_TYPE_MASK) == PWM_CAPTURE_TYPE_BOTH) { LOG_ERR("Cannot capture both period and pulse width"); return -ENOTSUP; } data->capture[pair].callback = cb; data->capture[pair].user_data = user_data; param = &data->capture[pair].param; if ((flags & PWM_CAPTURE_MODE_MASK) == PWM_CAPTURE_MODE_CONTINUOUS) { param->mode = kFTM_Continuous; } else { param->mode = kFTM_OneShot; } if (flags & PWM_CAPTURE_TYPE_PERIOD) { data->capture[pair].pulse_capture = false; if (flags & PWM_POLARITY_INVERTED) { param->currChanEdgeMode = kFTM_FallingEdge; param->nextChanEdgeMode = kFTM_FallingEdge; } else { param->currChanEdgeMode = kFTM_RisingEdge; param->nextChanEdgeMode = kFTM_RisingEdge; } } else { data->capture[pair].pulse_capture = true; if (flags & PWM_POLARITY_INVERTED) { param->currChanEdgeMode = kFTM_FallingEdge; param->nextChanEdgeMode = kFTM_RisingEdge; } else { param->currChanEdgeMode = kFTM_RisingEdge; param->nextChanEdgeMode = kFTM_FallingEdge; } } return 0; } static int mcux_ftm_pin_enable_capture(const struct device *dev, uint32_t pwm) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; uint32_t pair = pwm / 2U; if (pwm & 0x1U) { LOG_ERR("PWM capture only supported on even channels"); return -ENOTSUP; } if (pair >= ARRAY_SIZE(data->capture)) { LOG_ERR("Invalid channel pair %d", pair); return -EINVAL; } if (!data->capture[pair].callback) { LOG_ERR("PWM capture not configured"); return -EINVAL; } if (FTM_GetEnabledInterrupts(config->base) & BIT(PAIR_2ND_CH(pair))) { LOG_ERR("Capture already active on channel pair %d", pair); return -EBUSY; } FTM_ClearStatusFlags(config->base, BIT(PAIR_1ST_CH(pair)) | BIT(PAIR_2ND_CH(pair))); FTM_SetupDualEdgeCapture(config->base, pair, &data->capture[pair].param, CONFIG_PWM_CAPTURE_MCUX_FTM_FILTER_VALUE); FTM_EnableInterrupts(config->base, BIT(PAIR_1ST_CH(pair)) | BIT(PAIR_2ND_CH(pair))); return 0; } static int mcux_ftm_pin_disable_capture(const struct device *dev, uint32_t pwm) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; uint32_t pair = pwm / 2U; if (pwm & 0x1U) { LOG_ERR("PWM capture only supported on even channels"); return -ENOTSUP; } if (pair >= ARRAY_SIZE(data->capture)) { LOG_ERR("Invalid channel pair %d", pair); return -EINVAL; } FTM_DisableInterrupts(config->base, BIT(PAIR_1ST_CH(pair)) | BIT(PAIR_2ND_CH(pair))); /* Clear Dual Edge Capture Enable bit */ config->base->COMBINE &= ~(1UL << (FTM_COMBINE_DECAP0_SHIFT + (FTM_COMBINE_COMBINE1_SHIFT * pair))); return 0; } static void mcux_ftm_capture_first_edge(const struct device *dev, uint32_t pwm) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; struct mcux_ftm_capture_data *capture; uint32_t pair = pwm / 2U; __ASSERT_NO_MSG(pair < ARRAY_SIZE(data->capture)); capture = &data->capture[pair]; FTM_DisableInterrupts(config->base, BIT(PAIR_1ST_CH(pair))); capture->first_edge_overflows = data->overflows; } static void mcux_ftm_capture_second_edge(const struct device *dev, uint32_t pwm) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; uint32_t second_edge_overflows = data->overflows; struct mcux_ftm_capture_data *capture; uint32_t pair = pwm / 2U; uint32_t overflows; uint32_t first_cnv; uint32_t second_cnv; uint32_t cycles = 0; int status = 0; __ASSERT_NO_MSG(pair < ARRAY_SIZE(data->capture)); capture = &data->capture[pair]; first_cnv = config->base->CONTROLS[PAIR_1ST_CH(pair)].CnV; second_cnv = config->base->CONTROLS[PAIR_2ND_CH(pair)].CnV; /* Prepare for next capture */ if (capture->param.mode == kFTM_Continuous) { FTM_ClearStatusFlags(config->base, BIT(PAIR_2ND_CH(pair))); } /* Calculate cycles, check for overflows */ overflows = second_edge_overflows - capture->first_edge_overflows; if (overflows > 0) { if (u32_mul_overflow(overflows, config->base->MOD, &cycles)) { LOG_ERR("overflow while calculating cycles"); status = -ERANGE; } else { cycles -= first_cnv; if (u32_add_overflow(cycles, second_cnv, &cycles)) { LOG_ERR("overflow while calculating cycles"); cycles = 0; status = -ERANGE; } } } else { cycles = second_cnv - first_cnv; } LOG_DBG("pair = %d, overflows = %u, cycles = %u", pair, overflows, cycles); if (capture->pulse_capture) { capture->callback(dev, pair, 0, cycles, status, capture->user_data); } else { capture->callback(dev, pair, cycles, 0, status, capture->user_data); } if (capture->param.mode == kFTM_OneShot) { FTM_DisableInterrupts(config->base, BIT(PAIR_2ND_CH(pair))); } else { FTM_EnableInterrupts(config->base, BIT(PAIR_1ST_CH(pair))); } } static void mcux_ftm_isr(const struct device *dev) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; uint32_t flags; uint32_t irqs; uint32_t ch; flags = FTM_GetStatusFlags(config->base); irqs = FTM_GetEnabledInterrupts(config->base); if (flags & kFTM_TimeOverflowFlag) { data->overflows++; FTM_ClearStatusFlags(config->base, kFTM_TimeOverflowFlag); } for (ch = 0; ch < MAX_CHANNELS; ch++) { if ((flags & BIT(ch)) && (irqs & BIT(ch))) { if (ch & 1) { mcux_ftm_capture_second_edge(dev, ch); } else { mcux_ftm_capture_first_edge(dev, ch); } } } } #endif /* CONFIG_PWM_CAPTURE */ static int mcux_ftm_get_cycles_per_sec(const struct device *dev, uint32_t pwm, uint64_t *cycles) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; *cycles = data->clock_freq >> config->prescale; return 0; } static int mcux_ftm_init(const struct device *dev) { const struct mcux_ftm_config *config = dev->config; struct mcux_ftm_data *data = dev->data; ftm_chnl_pwm_config_param_t *channel = data->channel; ftm_config_t ftm_config; int i; if (config->channel_count > ARRAY_SIZE(data->channel)) { LOG_ERR("Invalid channel count"); return -EINVAL; } if (clock_control_get_rate(config->clock_dev, config->clock_subsys, &data->clock_freq)) { LOG_ERR("Could not get clock frequency"); return -EINVAL; } for (i = 0; i < config->channel_count; i++) { channel->chnlNumber = i; channel->level = kFTM_NoPwmSignal; channel->dutyValue = 0; channel->firstEdgeValue = 0; channel++; } FTM_GetDefaultConfig(&ftm_config); ftm_config.prescale = config->prescale; FTM_Init(config->base, &ftm_config); #ifdef CONFIG_PWM_CAPTURE config->irq_config_func(dev); FTM_EnableInterrupts(config->base, kFTM_TimeOverflowInterruptEnable); data->period_cycles = 0xFFFFU; FTM_SetTimerPeriod(config->base, data->period_cycles); FTM_SetSoftwareTrigger(config->base, true); FTM_StartTimer(config->base, config->ftm_clock_source); #endif /* CONFIG_PWM_CAPTURE */ return 0; } static const struct pwm_driver_api mcux_ftm_driver_api = { .pin_set = mcux_ftm_pin_set, .get_cycles_per_sec = mcux_ftm_get_cycles_per_sec, #ifdef CONFIG_PWM_CAPTURE .pin_configure_capture = mcux_ftm_pin_configure_capture, .pin_enable_capture = mcux_ftm_pin_enable_capture, .pin_disable_capture = mcux_ftm_pin_disable_capture, #endif /* CONFIG_PWM_CAPTURE */ }; #define TO_FTM_PRESCALE_DIVIDE(val) _DO_CONCAT(kFTM_Prescale_Divide_, val) #ifdef CONFIG_PWM_CAPTURE #define FTM_CONFIG_FUNC(n) \ static void mcux_ftm_config_func_##n(const struct device *dev) \ { \ IRQ_CONNECT(DT_INST_IRQN(n), DT_INST_IRQ(n, priority), \ mcux_ftm_isr, DEVICE_DT_INST_GET(n), 0); \ irq_enable(DT_INST_IRQN(n)); \ } #define FTM_CFG_CAPTURE_INIT(n) \ .irq_config_func = mcux_ftm_config_func_##n #define FTM_INIT_CFG(n) FTM_DECLARE_CFG(n, FTM_CFG_CAPTURE_INIT(n)) #else /* !CONFIG_PWM_CAPTURE */ #define FTM_CONFIG_FUNC(n) #define FTM_CFG_CAPTURE_INIT #define FTM_INIT_CFG(n) FTM_DECLARE_CFG(n, FTM_CFG_CAPTURE_INIT) #endif /* !CONFIG_PWM_CAPTURE */ #define FTM_DECLARE_CFG(n, CAPTURE_INIT) \ static const struct mcux_ftm_config mcux_ftm_config_##n = { \ .base = (FTM_Type *)DT_INST_REG_ADDR(n),\ .clock_dev = DEVICE_DT_GET(DT_INST_CLOCKS_CTLR(n)), \ .clock_subsys = (clock_control_subsys_t) \ DT_INST_CLOCKS_CELL(n, name), \ .ftm_clock_source = kFTM_FixedClock, \ .prescale = TO_FTM_PRESCALE_DIVIDE(DT_INST_PROP(n, prescaler)),\ .channel_count = FSL_FEATURE_FTM_CHANNEL_COUNTn((FTM_Type *) \ DT_INST_REG_ADDR(n)), \ .mode = kFTM_EdgeAlignedPwm, \ CAPTURE_INIT \ } #define FTM_DEVICE(n) \ static struct mcux_ftm_data mcux_ftm_data_##n; \ static const struct mcux_ftm_config mcux_ftm_config_##n; \ DEVICE_DT_INST_DEFINE(n, &mcux_ftm_init, \ NULL, &mcux_ftm_data_##n, \ &mcux_ftm_config_##n, \ POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE, \ &mcux_ftm_driver_api); \ FTM_CONFIG_FUNC(n) \ FTM_INIT_CFG(n); DT_INST_FOREACH_STATUS_OKAY(FTM_DEVICE)